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Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

image Wastewater
being discharged from
a pipe from the Youngor
textiles factory, in
Yinzhou district, Ningbo.
Youngor is a major
apparel and textiles
brand in China.

Contents
Executive Summary 

4

For more information contact:
[email protected]

Section 1 Introduction: Water crisis, toxic pollution
and the textile industry

10


Section 2 Polluters and their customers – the chain of evidence

32

Case Study 1: Youngor Textile Complex, Yangtze River Delta  36
Case Study 2: Well Dyeing Factory, Pearl River Delta

46

Section 3 The need for corporate responsibility 

54

Section 4 Championing a toxic-free future: Prospects
and recommendations 

72

Acknowledgements:
We would like to thank the following
people who contributed to the creation of
this report. If we have forgotten anyone,
they know that that our gratitude is also
extended to them:
Jamie Choi, Madeleine Cobbing,
Tommy Crawford, Steve Erwood,
Marietta Harjono, Martin Hojsík, Zhang Kai,
Li Yifang, Tony Sadownichick,
Melissa Shinn, Daniel Simons, Ilze Smit,
Ma Tianjie, Diana Guio Torres, Vivien Yau,
Yue Yihua, Zheng Yu, Lai Yun, Lei Yuting
Designed by:
Atomo Design

Cover photograph:
Appendix 1 
Pipe on the north side of the
81
1) M
 ain brands that have a business relationship
Youngor factory has finished
with Youngor Textile Complex
dumping wastewater. The black
polluted discharge is clearly visible
2) M
 ain brands that have a business relationship with
© Greenpeace / Qiu Bo
Well Dyeing Factory Limited
JN 372

3) The global market shares of sportwear companies
Appendix 2 
Profiles of other brands linked with Youngor Textile Complex

92
Published by

Appendix 3 
96
Greenpeace International
Background information on the hazardous
Ottho Heldringstraat 5
chemicals found in the sampling
1066 AZ Amsterdam
References 

The Netherlands

102
greenpeace.org

Note to the reader
Throughout this report we refer to the terms ‘Global North’ and ‘Global South’ to describe two distinct groups of countries.
The term ‘Global South’ is used to describe developing and emerging countries, including those facing the challenges of
often rapid industrial development or industrial restructuring, such as Russia. Most of the Global South is located in South
and Central America, Asia and Africa.
The term ‘Global North’ is used for developed countries, predominantly located in North America and Europe, with high
human development, according to the United Nations Human Development Index.* Most, but not all, of these countries
are located in the northern hemisphere.
* United Nations Development Programme (UNDP). (2005). Human Development Report 2005. International cooperation at a
crossroads. Aid, trade and security in an unequal world. Available at: http://hdr.undp.org/en/media/HDR05_complete.pdf

© GREENPEACE /QIU BO

The problem
and the
solution are not
only a cause of
local concern.
This is truly a
global issue.
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

3

image Opposite the discharge
pipe is the high-end housing
development ‘Vanke Golden
Banks’. The Fenghua River is
hardly ever golden these days,
but rather turbid, black or red
depending on the wastewater
dumped from the pipe.

A recent survey of
15,000 people in 15
countries, across both
northern and southern
hemispheres, found
that water scarcity and
water pollution are the
two top environmental
concerns of the
world’s population.
4

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QIU BO

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Executive
Summary

Executive
Summary
Dirty Laundry
The toxic secret behind global textile brands
Unravelling the toxic threads
Building upon Greenpeace’s recent
investigations, Dirty Laundry profiles the
problem of toxic water pollution that results
from the release of hazardous chemicals by the
textile industry in China. This water pollution
poses serious and immediate threats to both
our precious ecosystems and to human health.
Urgent and transparent action is needed in
order to eliminate the use and release of these
hazardous chemicals.
Leading clothing brands source many of their products from
suppliers in China. Although some of these brands have
Corporate Responsibility programmes which partly address
the environmental impact of their supply chain, none of the
brands featured in this report have an effective strategy in
place to deal with the problem of water pollution caused
by industrial discharges containing hazardous substances.
At best, the majority of these programmes are limited to
ensuring that suppliers comply with local standards – most
of which rarely consider the discharge of the hazardous and
persistent chemicals highlighted in this report. It is clear that
these leading brands have not yet made a significant effort
to tackle the problem of eliminating the release of hazardous
chemicals during the production process.

Key findings of the investigations

brands were also undertaken. The results from these
samples are indicative of a much wider problem.
• The scientific analysis of the samples found that both
manufacturing facilities were discharging a range of
hazardous chemicals into the Yangtze and Pearl River
deltas. Significantly, hazardous and persistent
chemicals with hormone-disrupting properties
were found in the samples. Alkylphenols (including
nonylphenol) were found in wastewater samples from both
facilities, and perfluorinated chemicals (PFCs), in particular
perfluorooctanoic acid (PFOA) and perfluorooctane
sulphonate (PFOS), were present in the wastewater from
the Youngor Textile Complex. This was despite the
presence of a modern wastewater treatment plant
at the Youngor facility. The alkylphenols and PFCs found
in the samples are a cause for serious concern, as these
chemicals are known hormone disruptors and can be
hazardous even at very low levels. Many of the substances
within these groups are regulated in the Global North, for
example by the EU or by international conventions.
• Our investigations further revealed that the companies
behind the two facilities have commercial relationships
(as suppliers) with a range of major brands, including
Abercrombie & Fitch, Adidas, Bauer Hockey,
Calvin Klein, Converse, Cortefiel, H&M, Lacoste,
Li Ning, Meters/bonwe, Nike, Phillips-Van Heusen
Corporation (PVH Corp), Puma and Youngor, and
have also been linked with a number of other Chinese and
international brands. When confirming their commercial
relationship with the Youngor Group, Bauer Hockey,
Converse, Cortefiel, H&M, Nike and Puma informed
Greenpeace that they make no use of the wet processes of
the Youngor Group for the production of their garments.

• The investigations that form the basis of this report focus
on wastewater discharges from two facilities in China.
The first facility, the Youngor Textile Complex, is located
on the Yangtze River Delta. The second, Well Dyeing
Factory Limited, is located on a tributary of the Pearl
However, regardless of what the aforementioned brands
River Delta. Additional investigations into the supply
use these facilities for, none of these brands have in
chains that tie these facilities to national and international place comprehensive chemicals management policies

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

5

that would allow them to have a complete overview of
the hazardous chemicals used and released across their
entire supply chain and to act on this information. As
brand owners, they are in the best position to influence
the environmental impacts of production and to work
together with their suppliers to eliminate the releases of all
hazardous chemicals from the production process and
their products. These brands need to take responsibility
for the use and release of persistent, hormone-disrupting
chemicals into our critical and life-sustaining waterways.
A commitment to zero discharge of hazardous chemicals
along with a plan on how to achieve this is urgently needed
in order to prevent the further accumulation of hazardous
substances in the aquatic environment, and the resulting
build-up in people and wildlife.

A persistent problem
The dangers associated with the use and release of
persistent hazardous chemicals have been recognised,
in part, by many countries in the Global North. There,
policies to reduce the use and release of some priority
hazardous chemicals have been implemented. Attempts
to clean up some of the worst effects of decades of toxic
pollution are underway, despite the very high expense
of restoration programmes and the impossibility of total
decontamination. By comparison, less progress has been
made in many parts of the Global South to reduce the use
and release of hazardous chemicals. Subsequently, lower
costs and simpler regulation is something that many global
brands have taken advantage of, by locating production
facilities in these areas or purchasing goods from facilities
located in the Global South.
Among the numerous chemicals used and released by
industry, persistent substances – such as heavy metals
and some hazardous organic chemicals – are a source of
particularly high concern.
These hazardous chemicals pose long-term threats to
human health and the environment. What makes many
of these chemicals so dangerous is that they are not only
persistent (meaning that they do not readily break down in
the environment), but also bioaccumulative (meaning that
they can build up in the food chain and can have serious,
long-term effects on the organisms that ingest them).
Some are able to interfere with hormone systems in
people and wildlife, even at very low doses, while others
are carcinogenic or reprotoxic.
Furthermore, the effects of such persistent and
bioaccumulative substances are not confined to local or
regional areas. Many can be transported far beyond their
6

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

release point via ocean currents, atmospheric deposition
and food chains. Some are even transported to remote
locations, such as the polar regions, where they can
accumulate. The problem and the solution are therefore
not only a cause of local concern. This is a truly global issue.

Water pollution: Made in China
China has some of the worst water pollution in the world,
with as much as 70% of its rivers, lakes and reservoirs
being affected by all types of pollutants. About 20% of the
organic pollutants from all sources in China are accounted
for by discharges from industry.1 However, the contribution
of persistent, hazardous chemicals to this pollution is not
properly assessed and remains largely unknown.
To explore this problem further, in 2009 Greenpeace
investigated five facilities discharging industrial wastes
into the Pearl River Delta and found a variety of hazardous
chemicals in their wastewater. There are also signs that
persistent chemicals are building up in Chinese rivers;
studies have detected the persistent and hormonedisrupting pollutants alkylphenols and PFCs in fish
species along the Yangtze River.2
Clearly, the current approach to pollution control – which
relies on wastewater treatment plants, ambient quality
standards and limits on certain pollutants in effluent – has
not prevented industrial water pollution by hazardous and
persistent chemicals. In fact, treatment plants are unable
to remove many of these substances from wastewater,
meaning that they either pass through the treatment process
unchanged, are converted into other hazardous substances,
or accumulate in treatment plant residues, such as sludge.

Textile production and its links
to the pollution
The modern textile industry has a long history of migrating
from one region or country to another. Most of this migration
has been driven by one factor: the need to cut costs.
As well as being an important sector in China’s economy,
accounting for 7.6% of China’s total trade volume3, the
textile industry is a large user of chemicals, many of which
are hazardous and persistent, and is reported to be a major
source of water pollution. The ‘wet processing’ of textiles,
including dyeing, washing, printing and fabric finishing
leads to the discharge of large quantities of wastewater
containing toxic substances.
Although large-scale pollution from the textile industry has
been a problem throughout its history, the more recent use
of persistent and hazardous chemicals poses a greater, and
often invisible, threat to ecosystems and human health.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Executive
Summary

Corporate connections and the
skeletons in their closets
The global textile supply chain is complex, involving many
different stages and actors. Multinational brand owners
may contract suppliers directly or indirectly, through
agents or importers. Normally, it is the brand owner who
triggers the product development process, including
research and design. Brand owners are therefore
the best placed to bring about change in the
production of textiles and clothing - through their
choices of suppliers, the design of their products and
the control they can exert over the use of chemicals in
the production process and the final product.
The international and Chinese brands connected to
the suppliers investigated in this report vary greatly
in their approach to environmental sustainability
and corporate social responsibility (CSR). Some
of the brands – such as Li Ning, Bauer Hockey,
Abercrombie & Fitch and Youngor – carry out
little or no reporting on CSR issues. They do not
publish a chemicals management policy, nor do
they make publically available lists of chemicals
banned or restricted in their products or during their
manufacture. In contrast, the sportswear brands
Nike, Adidas and Puma, fashion brands such as
H&M and apparel companies such as Phillips-Van
Heusen all publish more detailed information about
their approach to managing hazardous substances
in their products4 (see Appendix 1 for details).
The policies and practices of Nike, Adidas and
Puma were examined in particular detail for this
report, due in part to the fact that all three have
been recognised by external bodies – such as the
Dow Jones Sustainability Index5 – as leaders on
sustainability issues. As part of this investigation,
particular attention was paid to those policies and
practices relating to the discharge of hazardous
substances into water by their supply chains.
Nike, Adidas and Puma all have detailed restricted
substances lists specifying which substances
must not be present above certain limits in their
final products. However, there is no evidence that
any of the brands implement measures to restrict
the release of most hazardous substances into
water via their suppliers’ wastewater discharges,
beyond the requirements of local legislation.

e held
Factories will b
d liable
responsible an
damage
for all loss and
MA,
suffered by PU
rdous
should any haza
und
fo
substances be
,
in the materials
r final
components o
products.”
dbook of
PUMASafe: Han
6
dards 2009
an
Environmental St

“We also collaborate
with factories to
improve efficiency in
order to avoid borrowing
more water than is need
ed
and to be able to return it
as clean, or cleaner, than
it was found.”

“Our strategy
is to become a
zero-emissions
company”
Adidas website
7
[Green Company].

P.38, NIKE Inc Corporate
Responsibility Report FY 07
08 098

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

7

Responsibility for cleaning up

“We
a
prec pply the
autio
nary
in ou
pr
r
work environm inciple
a
e
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vent
adop
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H&M
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.”
nsc
ainab ious Act
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Sust

“We recognise that our supply
chain processes impact the
environment. While we do not
have direct control over our
suppliers, vendors and service
providers, we […] seek to have
our suppliers and vendors meet
our environmental requirements
with respect to wastewater
treatment, hazardous
chemicals, air quality and
recycling.”
Phillips-Van Heusen,
Environmental Statement10

8

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

China has yet to develop strong legislation, monitoring
and enforcement mechanisms to deal effectively with
the use of hazardous chemicals and their subsequent
discharge into water. Brands that source products from
China need to take the lead by accepting responsibility
for the problem of hazardous chemical discharges and
by implementing a series of measures throughout their
supply chains that go beyond the general ‘environmental
management’ approach apparent in some Corporate
Responsibility programmes.
This will require a change in the way that discharges of
hazardous chemicals are dealt with. As this investigation
has shown, even where modern wastewater treatment
plants exist – such as at the Youngor Textile Complex –
hazardous persistent chemicals can still be present in the
treated wastewaters. New strategies therefore need to be
adopted that will prevent the discharge of these chemicals
into our water supplies by eliminating their use altogether.
Stricter regulations and enforcement mean that in much
of the Global North the use of substances – such as
alkylphenols and many of the PFCs – is avoided in textile
manufacturing. In some instances, eliminating the use
of hazardous chemicals – such as alkylphenols – and
replacing them with a safer alternative has saved brands
money, and even kept companies in business. Substituting
with safer alternatives often enables the use and discharge
of hazardous chemicals to be completely eliminated.
Yet in countries such as China, hazardous chemicals
that endanger the health of people and wildlife – both
locally and globally – continue to be used, even though
alternatives exist. In fact, while the production of hazardous
chemicals such as PFOS and nonylphenols is falling
globally, it is actually on the increase in China.
It is therefore vital that brands intervene rapidly to instigate
a phase-out of hazardous chemicals throughout their
supply chains, starting with those that are known to be
highly problematic and that have already been regulated
elsewhere (see Section 4 for a list of 11 priority groups of
chemicals for phase-out by the textile sector). Given their
significant economic influence, the major brands
are in a unique position to lead on this phase-out
within the textile industry by setting a deadline for
elimination and developing a substitution plan. They
must ensure that adequate resources are devoted to
the development of alternatives, to enable substitutes to
become both available and economically viable.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

However, despite the urgent need for leadership and
real action on the ground from innovative brands
seeking first-mover advantage, if the shift to a toxic-free
future is to be effective it will also need to be enforced
throughout the industry. There is therefore also a need
for governments to put in place comprehensive
chemical management policies to facilitate the shift
from hazardous to non-hazardous chemicals.

Championing a better future
Toxic pollution has to be dealt with in all countries.
Hazardous, persistent and hormone-disrupting
chemicals continue to be used and released,
contaminating our waterways and threatening
our livelihoods and our future. As influential actors
implicated as part of a broken system, brands and
governments have a responsibility to act now.

The role of brands:
To this end, Greenpeace is calling on the brands and their
suppliers identified in this investigation to become the
champions for a post-toxic world – by eliminating
all releases of hazardous chemicals from their supply
chains and their products.
Specifically, this entails establishing clear company and
supplier policies that commit their entire supply chain to the
shift from hazardous to safer chemicals, accompanied by a
plan of action that is matched with clear and realistic timelines.
Proper policies to eliminate the use and release of all
hazardous chemicals across a company’s entire supply
chain should be based on a precautionary approach
to chemicals management, and account for the whole
product lifecycle and releases from all pathways. To
be credible, these policies need to be accompanied by
a plan of implementation, with clear timelines, and be
matched with real and substantial action on the ground.
Furthermore, steps such as knowing what hazardous
chemicals their suppliers use and release, being
transparent and accountable by making this data publicly
available, and prioritizing ‘known’ hazardous chemicals
for immediate elimination will be fundamental to their shift
towards championing a toxic-free future.
Above all these companies need to act as leaders and
innovators. The problems associated with the use and
release of hazardous chemicals within the textile industry
will not be fixed by severing ties with one or two polluting
suppliers. The solutions are to be found in working together
with suppliers to bring about systematic change in the way
brands and businesses create their products. Such action
requires vision, commitment and a desire to improve upon

Executive
Summary

the current approach to hazardous chemicals. Every brand
and supplier has the responsibility to know when and where
hazardous chemicals are being used and released up and
down their supply chain and to strive to eliminate them.
It will therefore be through their actions, not their
words, that these brands can become agents
of positive change.

The role of governments:
Greenpeace is calling on governments to adopt a political
commitment to ‘zero discharge’ of all hazardous
chemicals within one generation, based on the
precautionary principle and a preventative approach
to chemicals management.
This commitment must be matched with an implementation
plan containing intermediate short term targets, a dynamic
list of priority hazardous substances requiring immediate
action, and a publicly available register of data on discharge
emissions and losses of hazardous substances, such as
a Pollutant Release and Transfer Register (PRTR). These
steps must be taken to prevent further damage to the
environment and risks to health from future uses and
releases of hazardous and persistent chemicals, and to
avert the need for costly clean-up operations.
Governments have a choice. They can continue to
expose their citizens and the environment to hazardous toxic
pollution, and condemn future generations to pay for the
management of contaminated sediments, whose full and final
costs are incalculable. Or they can commit to creating a posttoxic world, by taking precautionary action to support truly
sustainable innovation, and progressively reduce the use and
release of hazardous substances down to zero.

The role of global citizens:
As global citizens, our power to stand up for what
we believe in and to collectively influence brands and
governments to make the right choices for us and future
generations has never been greater than it is today.
Please join with us and support Greenpeace in calling on
these brands to champion a post-toxic world – where
our water supplies are no longer polluted with hazardous,
persistent and hormone-disrupting chemicals by industry.
Together we can demand that they act NOW to detox our
rivers, detox our planet and ultimately, detox our future.
A post-toxic world is not only desirable, it’s possible.
Together we can help create it.

The time to act is now.
www.greenpeace.org/detox
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

9

image The flow of
wastewater from
this discharge pipe
increases at dusk; the
pipe leads into the
Huangsha Channel, and
is located northeast of
the Well Dyeing Factory
Ltd. A Greenpeace
campaigner is
investigating.

01

10

Dirty Laundry: Corporate connections to hazardous chemical water pollution by the textile industry in China

© GREENPEACE /QIU BO

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
one

01
Introduction:
Water crisis, toxic pollution
and the textile industry
A vital resource under threat
Clean water is both essential to the planet’s
ecosystems and fundamental to people’s
well being. It is a basic human right. As well
as providing a range of critical habitats for
wildlife, waterways such as rivers and lakes
supply communities with vital resources –
including drinking water, water for crop irrigation
and foods such as fish and shellfish. These
waterways also serve as a support system
for industrial activity, providing water for
many manufacturing and cooling processes.
However, such industrial activities can affect
water quality and thereby jeopardise the other
resources that the rivers and lakes provide.

A recent survey of 15,000 people in 15 countries, across
both northern and southern hemispheres, found that water
scarcity and water pollution are the two top environmental
concerns of the world’s population.1,2 Globally, water
resources are being degraded by the increasing pressure
of human activities. Economic and population growth
places ever-greater demands on water supplies, reducing
the quantity and quality of water available for wildlife,
ecosystem function and human consumption. The severity
of these impacts is summarised by the UN as follows:

of
lution
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and
letion er basins
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3
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w
of the

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

11

image Yellow
scum left behind
on the mud by the
flow of wastewater
from ‘Pipe 1’ at
the Youngor Textile
complex.

12

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE /QIU BO

Important
waterways in the
Global South are
also increasingly
threatened by
the build-up
of hazardous
substances, which
are impairing their
ecological health
and their capacity
to provide vital
resources.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
one

Nitrate and other nutrient pollution from agricultural runoff
and sewage have the most obvious and visible effect on
waterways, as they lead to the growth of algal blooms, which
in turn deplete oxygen supplies in water.

Important waterways in the Global South are also
increasingly threatened by the build-up of hazardous
substances, which are impairing their ecological health
and their capacity to provide vital resources. Examples
Hazardous chemicals can be released into waterways either of threatened waterways include the Chao Phraya in
directly (from industrial facilities) or indirectly (through the use Thailand, the Neva in Russia, the Marilao river system in
of industry’s products in agriculture or by consumers). Some the Philippines and the Riachuelo in Argentina. Coastal and
marine environments and resources also suffer knock-on
of these chemicals can persist in the environment, build up
in waterways and enter the food chain – impacting adversely effects from pollutants discharged by these waterways.
upon both wildlife and human health.
According to the United Nations Environment
Programme, “worldwide, it is estimated that industry
The Global North has many heavily industrialised freshwater
is responsible for dumping 300–500 million tons of
and estuarine systems – such as the Rhine-Meuse-Scheldt
Delta in Belgium and the Netherlands, and the Great Lakes in heavy metals, solvents, toxic sludge and other waste
into waters each year.”5
North America – where decades of pollution with persistent
hazardous chemicals have led to high concentrations of
contaminants in the sediments of rivers and harbours. In
many cases, this contamination has caused long-term,
irreversible damage to people, the environment and the
wider economy, which is a major cause of concern for local
communities, governments and industry.4

In high-income countries, industrial pollution is said to be
stabilising or decreasing. The Organisation for Economic
Co-operation and Development reports that since the
1970s, high-income countries have reduced industrial
discharges of heavy metals and other persistent chemicals
by 70% to 90% or more in most instances.6 However, this
is not the case for economies in the Global South, where
pollution is expected to increase along with economic and
industrial development.7

Dirty Laundry: Corporate connections to hazardous chemical water pollution by the textile industry in China

13

Water pollution in China:
causes, costs and concerns
has become
cade or so, China
“Over the last de
ices for
ty to undercut pr
ili
ab
its
r
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here
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ufacturers elsew
an
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ay
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. As Bill
machinery. The
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une magazine pu
rt
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not whether to m
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but how much an

China has some of the worst water
pollution in the world9, with as much as
70% of its rivers, lakes and reservoirs
being affected.10 China’s existing water
shortage problem is worsening due to spiralling
demand and the growing effects of climate
change. Water pollution is further exacerbating
the situation, with a quarter of the country’s
population having no access to clean drinking
water.11 Severe water shortfalls are predicted
for many regions across China if no action is
taken to tackle the problem.
According to a nationwide survey, industry accounted
for nearly 20% of organic pollutants (expressed as
Chemical Oxygen Demand)12 discharged into water in
2007.13 In many cases, the factories polluting critical water
sources are producing goods for the US and European
markets, with research indicating that about 20% to 30%
of China’s water pollution comes from manufacturing
goods for export.14
Industrial discharge of hazardous substances shows
no sign of abating, despite the fact that water pollution
is recognised by the Chinese authorities as a cause for
serious concern.15

14

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

The head of the State Environmental Protection
Administration (SEPA)16 acknowledged as long ago as
2006 that “in some places, environmental problems
have affected people’s health and social stability, and
damaged our international image”.17
Many people in China who have provided resistance to
the polluting industry share this concern. According to
the Ministry of Environmental Protection, anti-pollution
protests have been increasing by a third every year.18
A 2008 study of Chinese industry reports that: “Sometimes
not-in-my-backyard protests force the government to
move factories into less populated areas, where there will
be fewer people to complain.
While water pollution has severe impacts on the
environment, it also has direct economic consequences
for industry itself. The nationwide annual cost to industry of
using polluted water was estimated in a 2007 SEPA/World
Bank report at 50bn yuan ($7.5bn US dollars).19
According to the same source, the use of polluted
water for agricultural irrigation in designated
wastewater irrigation zones has an impact on yields
and product quality that was estimated at 7bn yuan
($1bn) in 2003.
The produce in these zones is likely to contain heavy
metals such as mercury, cadmium, lead, copper,
chromium and arsenic. Human health impacts, which are
harder to assess, were not considered in this study.

image A Greenpeace
campaigner takes
a sample of yellowcoloured wastewater
from the discharge
pipe of the Youngor
Textille Complex.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
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pollution in China

Section
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Box 1.1 The sinister effects
of hazardous chemicals in the
environment
Chemicals that cause particular concern when
released into the environment display one or more of
the following properties:
• persistence (they do not readily break down in
the environment);
• bioaccumulation (they can accumulate in
organisms, and even increase in concentration
as they work their way up a food chain); and
• toxicity.
Chemicals with these properties are described
as PBTs (persistent, bioaccumulative and
toxic substances). Organic chemicals with these
properties are sometimes referred to as persistent
organic pollutants (POPs), for example under the
global Stockholm Convention20. Despite initial dilution
in large volumes of water or air, such pollutants can
persist long enough in the receiving environment to
be transported over long distances, to concentrate
in sediments and organisms, and some can cause
significant harm even at what may appear to be very
low concentrations.
Heavy metals are inherently persistent and some of
them (for example cadmium, lead and mercury) are
also able to bioaccumulate and/or are toxic. Although
they occur naturally in rocks, their use by industry can
release them into the environment in quantities that
can damage ecosystems. Heavy metal compounds
do not break down into harmless constituents but can
react to form new compounds.
Some types of toxicity make it difficult to define ‘safe’
levels for substances, even at low doses, for example,
substances may be:
• carcinogenic (causing cancer), mutagenic
(able to alter genes) and/or reprotoxic (harmful
to reproduction); or
• endocrine disruptors (interfering with hormone
systems).

© GREENPEACE /QIU BO

Dirty Laundry: Corporate connections to hazardous chemical water pollution by the textile industry in China

15

Rivers under threat
Of the numerous chemicals released by industry, heavy
metals and hazardous organic substances are of particular
concern (see Box 1.1). Many such chemicals pose a
long-term threat to human health and eco-systems once
released into the environment. In addition, some chemicals
bioaccumulate – becoming more concentrated higher up
the food chain – and can have serious, long-term effects on
the organisms that ingest them.21 Furthermore, the effects
of such persistent and bioaccumulative substances can be
global, as they may be transported far beyond their source
via ocean currents, atmospheric deposition and food chains.
Some have even been found to accumulate in the polar
regions.22
The Yangtze River, also known as the Chang Jiang (‘Long
River’), is the longest river in China, while the Pearl River is
the third longest. The delta areas of these two rivers have
undergone rapid development in recent decades and
both are now home to a wide range of industrial activities.
Industrial pollution is pushing rivers in China, including the
Yangtze and the Pearl River, beyond their ecological limits.

The Pearl River
Southern China’s Pearl River Delta region illustrates
the severity of the country’s industrial water pollution.
Adjacent to the Hong Kong and Macau special
administrative regions, the Pearl River Delta has emerged
as one of the world’s most dynamic industrial zones.23

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K30

Invest H

Abundant water resources from the Pearl River and its
tributaries have long supported the region’s industrialisation,
to the extent that it is known as the “world’s factory”.24
The 2009 report Poisoning the Pearl – based on seven
The Pearl River basin also serves as a source of drinking
months of fieldwork in the Pearl River Delta by Greenpeace
water for the region’s 47 million inhabitants, including the
China – offered a snapshot of industrial water pollution
populations of Guangzhou and Hong Kong.25,26
with hazardous chemicals.31 The report focused on five
However, the water quality has deteriorated sharply since
separate facilities and/or industrial areas and found that
the region’s remarkable economic growth began in the late
all were discharging chemicals known or suspected to be
1970s, with more than 60% of its waterways now designated hazardous. Alarmingly, discharges from three of the five
as “polluted”.27 Between 2003 and 2007, industrial
facilities contained concentrations that exceeded the limits
wastewater discharges into the Pearl River Delta increased by set by Guangdong province. Of even greater concern
52%, from 1.6bn tonnes to 2.4bn tonnes.28 By 2007, industry was that several of the facilities were discharging various
was responsible for 75% of all the wastewater discharged into hazardous chemicals that are not monitored or regulated
the Pearl River Delta.29
under Guangdong’s effluent standards.

16

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© Greenpeace / JOHN NOVIS

Greenpeace
International

image Contaminated
land in the Pearl River
Delta region.
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

17

image Heaps of trash
on the banks of he
Fenghua River; the
wastewater from Youngor
Textile Complex is also
discharged into this river.

18

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Section
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© GREENPEACE / QiU BO

Greenpeace
International

Water quality
has deteriorated
sharply since
the region’s
remarkable
economic growth
began in the late
1970s, with more
than 60% of its
waterways now
designated as
‘polluted’.
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

19

The Yangtze River
Throughout China’s long history, the Yangtze River basin
has been a centre of cultural and industrial activity.32
Today, the area contributes around 40% of the nation’s
GDP,33 the equivalent of about $1.5 trillion US dollars.34
Since the economic reform of the late 1970s, thousands
of industrial zones have cropped up along the banks of
the Yangtze, forming the so-called ‘Yangtze Industrial
Belt’, which stretches through seven provinces. Industrial
development is particularly concentrated in the Yangtze
River delta region, which accounts for around onefifth of China’s entire economy.35 It encompasses 16
cities, including Shanghai, whose 20 million people are
dependent on the Yangtze for drinking water.36 The river
receives around 30bn tonnes of wastewater (including
domestic sewage) annually, some of it untreated.37,38

While a variety of chemicals are discharged into the river by
industry, perhaps the most insidious are the PBTs (see
Box 1.1). In the Yangtze River, PBTs are likely to be
discharged from industries such as textiles, chemicals,
plastics, and non-ferrous smelting and mining.
A range of organic pollutants, including persistent
substances, can already be found in the Yangtze.39
Among the many industrial chemicals entering the food
chain are the persistent hormone disruptors – known as
alkylphenols and perfluorinated chemicals – which are
widely used in the textile industry. Figure 1.140 shows how
substances in these two chemical groups are present in
the Yangtze River ecosystem and are bioaccumulating
in fish species. This has potential consequences for
humans, given that the two species sampled are on the
daily menu of local communities.41

Persistent Chemicals in fish
1) The manufacturing of
alkylphenols (APs) and
perfluorinated chemicals (PFCs)
has fallen around the world, yet
in China their production is on
the rise.

2) Among the many industrial
chemicals entering the food chain
in the Yangtze are the persistent
and hormone-disrupting
pollutants alkylphenols (APs) and
perfluorinated chemicals (PFCs),
widely used in the textile industry.

3) Two alkylphenols
(4-nonylphenol (4-NP) and
nonylphenol ethoxylate (NPEO))
were found in water samples from
the Yangtze River near the city of
Chongqing.

4) Greenpeace samples of
popular edible fish, from locations
near four major cities along
the Yangtze, found APs in the
livers of all but one fish; the PFC
perfluoroctane sulfonate (PFOS),
was also detected in almost all
the samples.

5) Sediments collected from
the Yangtze River estuary have
yielded some of the highest PFOS
concentrations ever recorded.

20

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

6) The presence of the PFCs
PFOS and PFOA has also been
reported in tap water in many
cities in China, with some of the
highest concentrations found in
tap waters from Shanghai, Wuhan
and Nanjing on the Yangtze River.

Figure 1.1 The figure
shows how alkylphenols
and perfluorinated
chemicals are present
in the Yangtze River
ecosystem and how
they are bioaccumulating
in fish species

Greenpeace
International

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Unravelling the corporate
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pollution in China

Section
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© JOHN NOVIS / GREENPEACE

image Water highly
contaminated by
industrial discharge;
this tributary shows
no sign of life.

‘The river water
smells here - you
cannot even use
it for bathing, or
else you’ll itch all
over and break out
in spots all over
your body. Don’t
even think about
drinking this stuff.’
Xie Chunlin, fisherman, Jiangsu Province42

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

21

image Women
workers at
the Youngor
textiles factory in
Yinzhou district,
Ningbo.

Throughout China’s
long history, the
Yangtze River basin
has been a centre of
cultural and industrial
activity. Today, the
area contributes
around 40% of the
nation’s GDP, the
equivalent of $1.5
trillion US dollars.
22

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

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Section
one

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QIU BO

Greenpeace
International

23

Chemical use in the textile industry as a whole
The majority of chemical use in textile finishing processes
occurs during ‘wet processing’, such as dyeing, washing,
printing and fabric finishing.43 According to surveys
measuring natural resource use in all industries, textile
dyeing and finishing mills use considerably more water
than most – as much as 200 tonnes of water for every
tonne of textiles produced.44 Many of the chemicals
used in textile production are non-hazardous, but
a relatively small proportion of these chemicals are
potentially hazardous.45,46 However, in absolute terms a
considerably large number of hazardous chemicals are
used in textile production due to the very large number of
chemicals used.47

For example, the Swedish Chemical Agency has estimated
that there are over 10,000 substances usable in dyeing
and printing processes alone - about 3,000 of which are
commonly used. The availability of such a large number
of chemicals for use by industry poses obvious difficulties
when it comes to sharing and maintaining information
about them, as well as drawing up and enforcing
regulations for their use.
Figure 1.248 shows the different stages of textile and
garment production, with a focus on the wet processing
stage, where the hazardous chemicals highlighted in this
report are used. Chemicals might also be used in other
stages of textile production, in particular the production
of raw materials such as cotton, which also involves large
quantities of water and chemicals such as pesticides; this
is, however, beyond the scope of this report.

The stages of textile production
Figure 1.2 shows the
different stages of textile and
garment production, with a
focus on the wet processing
stage, where the hazardous
chemicals highlighted in this
report are used.

Large quantities of water
used and discharged
Man-made
fibres
Wet processing

Yarn
formation

Natural
fibres

24

Fabric
formation

Fabric
Finishing
■ preparation
■ dyeing
■ finshing
■ printing

Numerous chemicals
used, including some
hazardous substances

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Fabrication



cutting
sewing

Products

Dirty Laundry
Unravelling the corporate
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pollution in China

Section
one

© GREENPEACE /QIU BO

Greenpeace
International

image Coils and
bundles of cloth in a
production chamber
of the Well Dyeing
Factory Ltd.
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

25

Textiles in China: A major industry, a major polluter
The textile industry is an important sector of China’s
economy, with more than 50,000 textile mills in the
country.49 Textile imports and exports reached a record
high in 2010; the trade volume of textile products and
garments increased by 23.3% year on year, to $226.77bn
US dollars in 2010, accounting for 7.6% of China’s total
trade volume.50 The production and export of textiles is
concentrated in the eastern and south-eastern coastal
areas, including Guangdong, Zhejiang, Jiangsu, Shanghai
and Shandong.51 Guangdong province, which includes the
Pearl River Delta, accounts for 23% of China’s total textile
and clothing exports,52 while half the national textile industry
is located on the Yangtze River Delta.53 Across China there
are 164 textile industry clusters where companies specialise
in manufacturing certain products,54 for example Xintang,
‘the jeans capital of the world’ (see Box 1.2). Recently,
some textile industry clusters have relocated to western
and central China, encouraged by the State Council’s 2009
Textile Restructuring and Revitalisation Plan.55

However, the Chinese textile industry is built upon the
use of a large number of chemicals,59 and together with
the chemical industry is reported to be one of the most
polluting sectors in the country.60 Around 25% of the
chemical compounds produced worldwide are used to
a greater or lesser extent in the textile industry globally.61
Yet beyond very general pollution parameters – such as
chemical oxygen demand – there is very limited information
about the discharge of specific hazardous substances into
wastewater by Chinese textile manufacturers; or indeed by
any industrial sector.

Since the economic reforms of the 1970s, the textile industry
has become a dynamic part of China’s economic growth. At
the outset of the economic reform period, cheap land and
abundant labour meant that low value-added industries,
such as textiles, were the easiest to establish.56 In 1995
China became the largest exporter of textiles in the
world and it has maintained that position ever since.57

Wastewater is discharged from Top Dragon’s facility via
an underground channel, which flows into a tributary of
the Pearl River located approximately 100 metres from
the factory. Greenpeace investigators took samples from
the same discharge pipe twice, once during the day and
once at night. The data showed a degree of variation in
the quality of discharged wastewater between the two
samples. Key findings were the presence of nonylphenol
and two chemicals linked to dyeing and printing processes,
including a benzophenone derivative in the sample taken
during the day.63 The concentration of manganese
(5,390 μg/l) in the sample taken at night were in excess
of the upper limit set in Guangdong’s effluent standards
(2,000–5,000 μg/l).

Although the industry has hitherto been driven by exports
to the Global North, domestic demand for fashion is now
increasing, alongside the rise of the new middle class. By
the third quarter of 2010, the sector’s nominal retail value
growth had accelerated by 24% to reach 400bn yuan
($61bn US dollars) – up from an average of 18% in 2009 –
indicating stronger domestic demand for clothing, shoes,
hats and other textile products. This was in part a result
of improving consumer confidence, coupled with rising
income and strong government initiatives to boost domestic
consumption.58

26

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Through its investigations, Greenpeace China has
attempted to shed more light on the levels of toxic
contamination coming from industrial sources. One of the
companies investigated for Greenpeace China’s Poisoning
the Pearl report62 was the denim manufacturer Top
Dragon Textile Company, which carries out sizing, dyeing,
weaving and finishing at its facility in the city of Qingyuan,
Guangdong province.

According to the Qingyuan Environmental Protection
Bureau, Top Dragon was reported in 2008 as having
a bad environmental record due to “improper use of
water treatment facilities and pollutants in excess
of standards”.64

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
one

© GREENPEACE /john novis

image Top Dragon
Textile factory
located in Taihe
Industry complex, in
Qingyuan City, Guang
Dong Province. It
discharges waste
water into the Pearl
River Delta.

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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

27

Box 1.2 The dirty secret behind
your jeans
The manufacture of jeans illustrates some of the most
visible and gross pollution caused by China’s textile
and clothing industry. The economy of Xintang revolves
around the complete production process for jeans: from
spinning, dyeing and weaving to cutting, printing, washing,
sewing and bleaching. Xintang’s jeans and clothing
business began in the 1980s, and since then its output has
skyrocketed.
Factories are located along the river that flows into the
River Dong and further downstream into the Pearl River
Delta. The river was once pristine, but has since become
a black ditch dividing the village of Xizhou from the
industrial zone. The Xizhou villagers say that when the
factory discharges are severe, the river water is not merely
polluted, but toxic. The smell is putrid and unbearable,
and any skin contact results in itching and even septic
rashes. Though villagers once fished in the river and drank
its water, they now dare to do neither of these things, and
must pay for tap water.

“It’s n
o
want t that we d
them
o
to ma n’t
a pro
fit. M
ke
y
also
has t family
o
re
sewin
g jea ly on
n
a livin
s to m
g
a
prod . However ke
uctio
, the
np
must
be cl rocess
ea
not p
ollute n and
t
envir
onme he
nt.”

Lin Z
ho
Xizho 6 u (pseudo
u 6
n

ym),

28

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© LU GUANG / GREENPEACE

image Wastewater
discharged from a
denim washing factory
in Xintang, Zengcheng,
where the economy
is centred around
textile production.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
one

Inadequate regulation and enforcement
The existing system for controlling industrial discharges
was created as part of the Water Pollution Control Law,
which was enacted in 1984 and amended in 2008.67
It consists of a comprehensive system of ambient quality
standards and technology-based effluent standards. There
are also Cleaner Production Standards, which require
industries to reduce the use of toxic materials in general,
together with a list of key hazardous substances for clean
production auditing, pubished by MEP, which are related
to specific industries. However, there is no mandatory
regulation in China that requires industries to eliminate a
specific list of toxic chemicals.68
There are several key reasons why the system
underperforms69:
• It does not adequately address hazardous pollutants,
some of which - even in small amounts - can endanger
aquatic ecosystems and human health. Even in
Guangdong, where discharge standards are more
stringent, many highly hazardous chemicals found in
industrial effluents in the Pearl River delta region are
simply not regulated.

• There are intrinsic problems associated with the
pollution control approach and its emphasis on
wastewater treatment plants. While these are effective
at cleaning up certain types of pollution – such as
sewage or other biological wastes – they cannot cope
with many hazardous chemicals. Often, hazardous
chemicals will pass through the treatment process
unchanged to enter the food chain and build up in
downstream sediments. They can also be converted
into other hazardous substances and/or accumulate in
other wastes generated during the treatment process.
Hazardous wastes in the form of treatment plant
sludges are then created, which in turn are disposed
of into landfills or through incineration, releasing the
hazardous substances or their byproducts into the
environment.70,71

• Existing standards are inadequately enforced.
- Many companies cut costs by operating their
water pollution control equipment only when
they expect inspection visits.
- A large percentage of small and mediumsized businesses are not inspected due to
the Environmental Protection Bureau’s lack of
capacity and resources.
- Industry-related departments in local
government often interfere with the
enforcement of environmental laws in order
to protect revenues or employment.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

29

Corporations
and their
suppliers
have no right
to treat water
bodies as
their private
sewers.
30

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QiU BO

image Yellow
wastewater from ‘Pipe 1’
flows into the Fenghua
River. The pipe belongs
to the Youngor textiles
factory.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
one

Conclusion: Building a toxic-free future
Clean water is not only a basic human right;
it is the world’s most threatened essential
resource. Securing clean water for current and
future generations is essential for the health of
ecosystems and human societies alike. It will
also reduce the potential for resource conflicts,
which are widely seen as a likely consequence
of increasing water shortages. In this light,
corporations and their suppliers have no right to
treat water bodies as their private sewers.
Industrial pollution can have devastating impacts on river
systems and lakes that are vital to wildlife and to the lives
of billions of people. Toxic substances dumped by industry
have a wide range of harmful properties – such as causing
cancer, affecting the hormone system and interfering with
reproductive systems. These effects can apply not only
to humans, but to all living creatures. There are warning
signs that hazardous substances are building up in both
the Pearl and Yangtze rivers. Water quality is already
badly affected in the Pearl River, while the discovery of
hazardous chemicals in fish from the Yangtze shows that
action is urgently needed in both of these rivers.

The presence of hazardous substances in the environment
shows that the traditional approach to industrial discharges
is not working – wastewater treatment plants are simply
not able to cope with many hazardous substances. As
several decades of experience in the Global North have
shown, a regulatory system where licences are given for
the discharge of hazardous substances into wastewater
results in the legalised pollution of rivers and seas.72 The
consequences for ecosystems and human health are
severe, and the clean-up of hazardous substances is a
difficult and costly process.
What is needed is a new approach to hazardous chemicals
– one that addresses the problem at source rather than
retrospectively. The idea of eliminating all discharges
of hazardous chemicals into the aquatic environment –
‘zero discharge’ – is based on the understanding that
it is impossible to define safe levels for many hazardous
pollutants. Redesign of products and processes to phase
out the use and discharge of hazardous chemicals has
proven to be the best approach; policies and practices to
implement this will be outlined in sections 3 and 4.

The following section examines wastewater discharges
from two textile facilities in China, painting a more
accurate picture of the kinds of hazardous substances
There is evidence that the textile industry is responsible
routinely discharged by some factories in a ‘businessfor a large proportion of the water pollution problem in
as-usual’ scenario. It also outlines the product chains
China, with its use and discharge of hazardous chemicals
linking these facilities to well-known multinational
contributing to the chemical load in the important Pearl and
clothing corporations and brands – which must ultimately
Yangtze river systems.
take responsibility for the discharges and subsequent
contamination of our waterways.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

31

image The Youngor
factory discharges its
wastewater into the
Fenghua River. A black
ribbon of polluted
wastewater can be seen
in the water.

03
02
32

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QiU BO

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

02
Polluters and their customers
– the chain of evidence
Toxic discharges from two textile manufacturers
In 2010 and 2011, Greenpeace International
undertook an investigation to assess whether
hazardous chemicals were present in
wastewaters discharged from two textilemanufacturing facilities in China, and to provide
an indication of the types of chemicals currently
being used and released by such facilities1,2.
The first facility, the Youngor Textile Complex,
is located on – and discharges wastewaters
into – the Yangtze River Delta, while the second
facility, Well Dyeing Factory Limited, is located
on – and discharges wastewaters into –
a tributary of the Pearl River Delta.

The two sites were visited in June 2010 and samples
of discharged wastewaters and river sediments were
collected. In March 2011, further samples were collected
from the Youngor Textile Complex, to give more insight into
the quantities of hazardous chemicals identified.
The sampling process was co-ordinated by the
Greenpeace International Research Laboratories at Exeter
University in the UK. The samples collected in June 2010
were analysed by the Greenpeace International Research
Laboratories; those collected in March 2011 were sent for
analysis to Omegam Laboratoria in the Netherlands.
In addition, in order to understand the full chain of
evidence, Greenpeace undertook investigations to find out
which brands sourced clothing from these facilities.
The results presented in this report represent the key
findings of what was a detailed investigation; fuller data
on all the samples taken and a technical discussion are
provided in the Greenpeace Research Laboratories
Technical Note.3

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

33

Key findings of the investigation
This report finds that both manufacturing facilities
were discharging a range of hazardous chemicals into
the Yangtze and Pearl River deltas. Significantly, two
different groups of hazardous and persistent chemicals
with hormone-disrupting properties were found in
the samples: alkylphenols were found in wastewater
samples from both facilities, and perfluorinated
chemicals (PFCs) were found in wastewater from the
Youngor Textile Complex.

Connecting the links in the chain
of evidence
The fabric and clothing manufacturing industry commonly
relies on a mixture of longer-term and shorter-term
business relationships between brands and suppliers
(e.g. manufacturers of fabric or clothing – or both, in
the case of vertically integrated companies).
Our investigations focused on suppliers for whom we
have the following types of evidence:

The companies behind the two facilities have
commercial relationships (as suppliers) with a range
of major brands, including Abercrombie & Fitch,
Adidas, Bauer Hockey, Calvin Klein, Converse,
Cortefiel, H&M, Lacoste, Li Ning, Meters/bonwe,
Nike, Phillips-Van Heusen Corporation (PVH Corp),
Puma and Youngor, and have also been linked with
a number of other Chinese and international brands.
When confirming their commercial relationship with the
Youngor Group, Bauer Hockey, Converse, Cortefiel,
H&M, Nike and Puma informed Greenpeace that they
make no use of the wet processes of the Youngor
Group for the production of their garments.
However, regardless of what they use these facilities
for, none of the brands found to have commercial links
with these two facilities have in place comprehensive
chemicals management policies that would allow them
to have a complete overview of the hazardous chemicals
used and released across their entire supply chain, and
to act on this information. As brand owners, they are in
the best position to influence the environmental impacts
of production and to work together with their suppliers
to eliminate the releases of all hazardous chemicals from
the production process and products.

34

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

• direct evidence that a manufacturing facility belonging
to the supplier is discharging toxic materials; and
• evidence that major international (and domestic
Chinese) brands have business relationships with
the supplier.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

© GREENPEACE /QIU BO

image Greenpeace
campaigner is
taking a sample at
a discharge pipe.

Section
two

China has some
of the worst
water pollution
in the world, with
as much as 70%
of its rivers, lakes
and reservoirs
being affected.
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

35

Case study 1: Youngor Textile Complex,
Ningbo, Yangtze River Delta
image Main Entrance,
Youngor Textile
Complex

© GREENPEACE / QiU BO

Youngor Textile Complex –
location, products, discharges
Youngor Group Co Ltd4 is China’s largest integrated
textile company, with world-scale fabric manufacturing,
garment making and retailing capabilities. Established
in 1979, it is based in the city of Ningbo near
Shanghai, in the eastern province of Zhejiang. As well
as manufacturing fabrics and clothing for multiple
international brands, Youngor has its own product lines
that include shirts, suits, trousers, casual jackets, ties
and T-shirts, all officially recognised as leading national
brands.5

36

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

In 2003, Youngor Group Co Ltd invested 1bn yuan
($147m US dollars) to build the Youngor Textile Complex
in Ningbo, which includes “a large-scale production facility
for items such as high-quality dyed yarn cloth, wool fabric,
printed fabric, dyed fabric and knitwear”6. It is now one
of the major production facilities in China for high-end
clothing and textiles. The company’s headquarters at
the complex has a research centre, a warehouse and a
showroom in addition to the production facility.
The Youngor Textile Complex houses a number of
individual manufacturing plants, including those of the
subsidiaries Youngor Sunrise Textile Dyeing & Finishing
Co, Ltd (yarn dyeing, weaving, printing and finishing),

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

Ningbo Youngor Pants Co, Ltd (main product lines are
casual and formal trousers and sportswear)7, Ningbo
Youngor Fashion Co, Ltd (five product lines, the most
important of which is casual sportswear) and Ningbo
Youngor Worsted Spinning, Weaving & Dyeing Co, Ltd
(dyeing, spinning, weaving and finishing of worsted wool
fabric), as well as a wastewater treatment plant (WWTP).
Youngor Group Co Ltd states that it spent 3m yuan
($441,176) “to purchase a sewage treatment system
from Japan which uses advanced processing technology
to reduce emissions to safe levels, recycle water, and
conserve resources.”8

This large industrial complex occupies approximately
three kilometres of the Fenghua river frontage. The
Fenghua River, which flows into the Yangtze River Delta,
is tidal at this location. There are no other industrial
facilities with wastewater discharges into the river within
the vicinity of the Youngor Textile Complex discharge
pipe, which is connected to the WWTP (referred to by
Greenpeace as Pipe 1).

Youngor Textile Complex9
Figure 2.1 Sketch map of
the Youngor Textile Complex
showing the location
from which samples were
collected. Other samples (of
discharged water, rainwater
and river sediments) were
collected in the vicinity of
this site, as detailed in the
Technical Note.

Youngor International
Garment City

e
ridg
nB
a
i
x
Yin

nue
an Ave
Yinxi

Scale
250 Metres

Yinx
ian Ave
nue

Youngor
Textile
complex
Wastewater
treatment plant

Fenghua River

Pipe 1
Samples taken
June 2010
& March 2011

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

37

Connections to multinational
and domestic brands
The international clothing brands Adidas, Bauer Hockey,
Calvin Klein, Converse, Cortefiel, H&M, Lacoste,
Nike, Phillips Van Heusen Corporation (PVH Corp)
and Puma confirmed to Greenpeace that they have an
ongoing or recent business relationship with the Youngor
Group (including subsidiaries) based in Ningbo, China.
The Youngor Textile Complex also supplies the company’s
own brand, Youngor. Our analysis found that this very
same complex was discharging toxic chemicals into
the Fenghua River on the sampling dates between
June 2010 and March 2011.
When confirming their commercial relationship with the
Youngor Group, Bauer Hockey, Converse, Cortefiel, H&M,
Nike and Puma informed Greenpeace that they make no
use of the wet processes of the Youngor Group for the
production of their garments. However, none of the brands
found to have commercial links with these two facilities have
in place comprehensive chemicals management policies
that would allow them to have a complete overview of the
hazardous chemicals used and released across their entire
supply chain, and to act on this information.
Many of these companies have made public statements
about the need to avoid environmental pollution. According
to their respective websites, these companies seem to be
concerned about water quality. However, this investigation
found that toxic chemicals are being released into
surrounding water and local river systems by their supplier.

become a
“Our strategy is to
mpany by:
zero-emissions co
ronmental
• Embedding envi
erything
best practice in ev
we do
ronmental
• Maximising envi
efficiency gains
harnessing
• Supporting and
ion for a
our people’s pass
greener planet”
10
Adidas website

Although the Converse website does not refer to the
environment or sustainability, the Converse brand is
owned by Nike and is covered by the same corporate
responsibility report. Likewise, the Calvin Klein brand is
owned by Phillips-Van Heusen and is covered by the same
environmental statement. The Bauer website does not
mention the environment or sustainability. (See Appendix 1
for details of all the above companies and their responses
to the evidence presented in this report.)
38

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

“The clean production concept is
playing an increasingly important
role in Youngor’s cost-control.
Youngor’s management is now
fully aware of the importance
of environmentally friendly
production techniques.
Youngor Sunrise Textile and
Garment Company is presently
applying for the “Clean
Production Company” licence
from China’s National Cleaner
Production Center. The company
is taking this opportunity to further
promote cleaner production and
the use of green energy.”

Section
two

“Factories are responsible
for ‘harmful substances
free’ production. Factories
will be held responsible
and liable for all loss and
damage suffered by PUMA,
should any hazardous
substances be found in the
materials, components or
final products.”
Puma Handbook of Environmen
tal
Standards12

Youngor website11

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

39

“Respect fo
r the
environmen
t: It must b
e
ensured co
mpliance w
it
h
the environ
mental law
s
and regulati
ons applica
ble
in each cas
e, adopting
a
behaviour p
rinciple of a
responsible
and respec
tful
attitude tow
ards the
environmen
t.”
Grupo Cort
efiel, Extern
al Code
of Conduct 13

40

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

h
aborate wit
“We … coll
improve
factories to
order to
efficiency in
wing more
avoid borro
nd
is needed a
water than
return it as
to be able to
it
aner, than
clean, or cle
was found.”

ty

onsibili
rporate Resp 14
Nike Inc Co
8
7 08 09, p3
Report FY 0

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Lacoste does not have a
statement of CSR policy
but supports crocodile
conservation projects: “Using
for over 78 years a crocodile
as a logo, the LACOSTE brand
actively support projects
selected by the GEF to
safeguard or protect certain
species of crocodiles, alligators,
caiman or gavials now in danger
s
of extinction and whose the los
l
would jeopardize the biologica

as.
balance of their habitat are
Lacoste Press Kit

15

Section
two

We apply the
precautionary
principle in our
environmental work
and have adopted a
preventative approach
with the substitution of
hazardous chemicals.”
H&M Conscious Actions
Sustainability Report 201016

“We recognis
e that our su
pply
chain proces
ses impact th
e
environment.
While we do
not
have direct c
ontrol over o
u
r
suppliers, ve
ndors and se
rvice
providers, w
e […] seek to
have
our suppliers
and vendors
meet our env
ironmental
requirements
with respect
to wastewate
r treatment,
hazardous c
hemicals, air
quality and re
cycling.”
Phillips-Van H
eusen, Enviro
nmental
Statement 17

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

41

Which other firms are linked to
Youngor Group Co Ltd by this
chain of evidence?
Greenpeace also has evidence that the major brands
Blazek, Nautica, Macy’s, the Oxford Apparel Group
and Ralph Lauren have had a business relationship with
the Youngor Group Co Ltd in the recent past, but these
companies did not respond to a request for comment.
Peerless Clothing confirmed a recent business
relationship that it indicates has now ended.

Oxford
Apparel

42

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to hazardous
chemical water pollution by
the textile industry in China

Hazardous chemicals at the
end of the pipe
The Youngor Textile Complex is a large industrial complex
situated in Ningbo, on the banks of the Fenghua river,
which flows into the Yangtze river delta. Wastewater
samples from a pipe (referred to by Greenpeace as
‘Pipe 1’) that discharges from the complex’s wastewater
treatment plant were collected in June 2010 and again
in March 2011. Two samples were collected in June
2010: one was collected during the evening of 21 June,
when the flow of wastewater from the pipe was relatively
low; the other was collected on the morning of 22 June,
at which time the rate of discharge was observed to be
substantially greater.

Section
two

The levels found in the samples may appear to be low, but
they are similar to levels that have been found in wastewater
treatment plants receiving industrial effluent, and are above
background concentrations in surface waters.18

A chemical cocktail
A diverse array of other chemicals at low concentrations
was found in the samples taken in March 2011, indicating
that this wastewater is a source of a range of hazardous
substances to the local aquatic environment. This chemical
cocktail could be a result either of the deliberate use of
these chemicals in the textile processing, or of the washing
out of chemical residues from yarn or textile products, from
manufacturers located elsewhere, that have been brought
to the site for processing. It presents an unknown hazard,
as it is impossible to predict the risks posed by such
complex mixtures of chemicals.

The further samples of wastewater taken in March 2011
were collected on three separate occasions on 8 and 9
March, within a total period of around 15 hours. During this Chemicals found in the quantitative analysis included:
period the colour and the temperature of the wastewater
• amines – aniline, 2-chloroaniline, methylaniline,
was observed to vary considerably over time. The chemical
ethylaniline and diethylaniline were quantified, as well
analysis found a variety of hazardous substances, including
as the carcinogenic o-anisidine;
the persistent chemicals nonylphenol and perfluorinated
• the chlorinated volatile compounds dichloroethane,
chemicals, despite the presence of a modern wastewater
trichloromethane (chloroform) and tetrachloroethene;
treatment plant.
and

Nonylphenol

The most significant finding was the presence of nonylphenol
at a concentration of 14μg/l in one of the samples, collected
at 11am on 8 March 2011. Nonylphenol is a persistent,
manmade substance that can build up in the food chain and
is known to be a hormone disruptor.

• di-, tri- and pentachlorophenols.

The qualitative analysis of the sample taken in June
2010 detected 53 organic chemicals, though it was only
possible to positively identify 12 of these. The substances
identified included a trialkyl phosphate (tributyl phosphate
(TBP)), as well as an anthraquinone derivative. Fewer
Its presence in one of the three samples collected in March organic chemicals were isolated from the second sample
2011 indicates that the Youngor Textile Complex is, at
collected the following morning, when the rate of discharge
least periodically, acting as a source of this hazardous
from the pipe was visibly greater. Nonetheless, of the four
chemical to the Fenghua River.
compounds that were identified, all were also present in
the sample collected the previous evening. These findings
Perfluorinated chemicals (PFCs)
highlight the potential for variability in the composition of
The presence of several PFCs was also confirmed
wastewaters discharged from single point sources over
in the samples collected on all three occasions in
time. (See Appendix 3 for a list of the substances identified
March 2011; the highest concentrations were of
and their effects.)
perfluorooctanoic acid (PFOA) at between 0.13 and
0.14μg/l. Lower concentrations of other PFCs were also
found (perfluorocarboxylic acids at 0.013–0.031μg/l and
perfluorooctane sulphonate (PFOS) at still lower levels
(0.0031–0.0087μg/l)). PFCs are manmade chemicals that
are known for their long persistence in the environment;
they can cause adverse effects on the liver and act as
hormone disruptors (see Box 2.1).

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

43

Box 2.1 Perfluorinated chemicals (PFCs)
Production and use

Bioaccumulation

PFCs are man-made chemicals that are not produced by
natural processes and hence never occur in nature other
than as a result of human activity. They are highly resistant
to chemical, biological and thermal degradation,19 and
many are also relatively insoluble in both water and oils.
Their unique properties have led to their widespread use as
water, grease and stain-repellent finishes for textiles and
papers; specialised industrial solvents and surfactants;
ingredients in cosmetics, plastics20,21, firefighting foams;
and ingredients in lubricants for high-temperature
applications22.

Unlike many persistent organic pollutants (POPs), PFOS
accumulates in the bodies of animals by binding to proteins
in the blood, thereby building up to particularly high levels in
liver tissue.29,30,31 Numerous studies have reported PFCs in
tissues of amphibians, fish, birds and mammals (from mice
to far larger mammals including whales and polar bears,32,33
as well as red and giant pandas from zoos and wildlife parks
in China34. In the aquatic environment, PFCs have been
reported in organisms at all levels of food webs.35

The PFCs manufactured over the past 60 years fall into
four broad categories:
1) Perfluoroalkyl Sulfonate (PFASs)
(the best-known is PFOS),
2) Perfluorinated Carboxylic Acid (PFCAs)
(the best-known is PFOA),
3) Fluoropolymers (the best known is
polytetrafluoroethylene (PTFE), marketed as
Teflon and widely used in clothing, being the
basis of Gore-tex and similar waterproof fabric
and for non-stick cookware)
4) Fluorotelomer alcohols (FTOHs).23

Human exposure to perfluorinated
chemicals
PFOS and other PFCs have been found in blood and
breast milk from people living in many countries around the
world, even in remote areas such as the Canadian Arctic.
In the US, average concentrations of PFOS, PFOA and
Perfluorohexansulfonate (PFHxS) in blood samples have
fallen in recent years, perhaps due to the discontinuation of
industrial production of PFOS and related chemicals in the
US in 2002.36 Conversely, in Shenyang, China, levels
of PFOS and PFOA in human blood increased between
1987 and 2002.37 It has been suggested that sea fish
and other seafood may account for the majority of human
exposure in China.38,39

Distribution in the environment

Health impacts

However, the durability of this group of chemicals also
leads to potentially devastating consequences for the
environment, as it means that they persist for long periods
in nature once they are released, whether as a result
of manufacturing or disposal operations or during the
lifetime of a product.24 PFOS, for example, is a compound
so resistant to degradation that it is expected to persist
for very long periods in the environment.25 PFASs
(especially PFOS) and PFCAs (especially PFOA) have
been reported as contaminants in almost all environmental
media, including freshwater, groundwater and seawater
sediments and soils. Within China, PFCs including PFOS
and PFOA have been reported in various environmental
media including waters from many river systems.26,27,28

Studies of laboratory animals indicate that PFCs can cause
adverse impacts during both development and adulthood.
PFOS and PFOA have both been reported to have adverse
effects on the liver in rodents and monkeys.40,41,42,43
PFCs have also been shown to act as hormone disruptors44
in humans as well as other animals; for example, high
combined levels of PFOA and PFOS in the blood of men in
Denmark were found to be associated with a reduced count
of normal sperm.45

44

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

Regulation
In China there are currently no regulations governing the
manufacture and use of PFCs. However, PFOS has recently
been included among the POPs regulated by the Stockholm
Convention, a global treaty to protect human health and
the environment from the effects of POPs. Contracting
parties to the Convention (including China) are required to
take measures to restrict the production and use of PFOS,
although a wide range of uses are currently exempt.46
China is a contracting party to the Stockholm Convention,
although it hasn’t ratified the more recent amendment
addressing PFOS.47
The marketing and use of PFOS have also been prohibited
for certain applications within the EU48 and in Canada49,
although many exemptions exist to those under the
Stockholm Convention. Moreover, none of these
restrictions apply to PFCAs and other PFCs. Furthermore,
even when all uses are discontinued, the high persistence
of PFOS and other PFCs will inevitably mean that they
continue to be in the environment for a long period.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

45

Case study 2: Well Dyeing Factory Limited,
Zhongshan, Pearl River Delta
image Main Entrance,
Well Dying Complex

© GREENPEACE / QiU BO

Well Dyeing Factory Limited –
location, products, discharges
Hazardous chemicals have also been found in the
wastewater released from the discharge pipe of Well
Dyeing Factory Limited, the second case study presented
in this report. The complex of Well Dyeing Factory Limited
is located in the Gao Ping Industry District, Sanjiao, in the
city of Zhongshan in Guangdong province. It is situated
on tributaries of the Pearl River Delta. The complex is
one of many dyeing facilities located within the Gao Ping
Industry District. It is a large complex including various
production plants and a wastewater treatment plant, as
well as a power generation plant, workers’ dormitories
and administration buildings. It manufactures a wide
variety of textiles including knitted fabrics, velour, fleece
and spandex. Other processes carried out include the
pre-production treatment of fibres, bleaching, dyeing and
textile finishing.50,51

46

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

The Well Dyeing complex is bordered to the west by the
Shiji River and to the east by the Gaosha River. These two
small rivers are both tributaries of the far larger Huangshali
Channel, a part of the Pearl River Delta, which ultimately
flows into the South China Sea (see Figure 2.2). The river
system is tidal at this location, though the Shiji River is
connected to the Huangshali channel by a sluice gate, which
controls the flow of water. Other facilities unconnected to
Well Dyeing are located nearby, and some of these also
appear to discharge wastewaters into the Shiji River.
Greenpeace investigations revealed Pipe 1 discharging
within the small channel right up to the Well Dyeing
complex’s perimeter wall, and on the other side of the
wall within 2 metres of its wastewater treatment plant.
Discharge water was sampled at a time when there
was no rain (or standing surface water) for several hours
preceding the sampling. This pipe discharges wastewater
sporadically into the small channel, and was only observed
to be discharging during the night. Our investigations
indicate the discharge source of this pipe is exclusive to
the Well Dyeing facility.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

Well Dyeing Factory Limited52
Figure 2.2 Sketch
map of the Well
Dyeing complex
showing the location
from which samples
were collected.
Other samples (of
discharged water and
river sediments) were
collected in the vicinity
of this site, as detailed
in the Technical Note.

Scale
250 Metres

a

gsh

an
Hu

el

ann

h
li C

Well Dyeing
Gaosha River

Pipe 1

Waste water
treatment plant
d
Roa

Road

Fenghua River
Shiji River

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

47

48

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QIU BO

image These pools store
wastewater produced from
the dyeing process; they
are part of the wastewater
treatment plant of the Well
Dyeing Factory Ltd.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

Connections to multinational and
domestic brands
The major brands Abercrombie & Fitch, Meters/
bonwe, Phillips-Van Heusen Corporation (PVH Corp)
and Chinese sportswear brand Li Ning confirmed to
Greenpeace that they have an ongoing or recent business
relationship with Well Dyeing Factory Limited in Zhongshan,
China. Our analysis found that this facility was discharging
toxic chemicals into the Shiji River in June 2010.
Phillip-Van Heusen Corporation’s statement can be found
on page 41 of this report. The Li Ning Company gives no
information on its corporate website concerning its policies
or actions on the environment or sustainability.53 (See
Appendix 1 for more information about all four of these
companies above, and their responses to the evidence
presented in this report.)

is a
“Sustainability
that we
global initiative
bout at
feel strongly a
& Fitch
Abercrombie
by our
and we stand
mitment
continued com
tal
to environmen
and
sustainability
54
fforts.”
compliance e

Which other firms are linked to
Well Dyeing Factory Limited by
this chain of evidence?

Abercrombie &

Greenpeace also has evidence that the major brands
Carter’s, JC Penny, Kohls, Semir and Yishion have
recently been supplied by the same complex, but these
companies did not respond to a request for comment.
American Eagle, GAP and Uniqlo have confirmed
a recent business relationship that they indicate
has ended.

Fitch

“The company sees
environmental protecti
on
as an important part
of its sustainable
development strategy
and aims to guide its
environmental protecti
on
and sustainable
development strategy
with reference
to international
standards.”55
Meters/bonwe

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

49

Hazardous chemicals at the end
of the pipe
A wide range of organic chemicals were identified in a
wastewater sample collected by Greenpeace in June
2010 from a pipe connected to the facility of Well Dyeing
(referred to by Greenpeace as ‘Pipe 1’, see Figure 2.2).
Organic substances identified included two types of
alkylphenols, nonylphenols and octylphenols, which are
hazardous and persistent substances with hormonedisrupting properties (see Box 2.2); others included trialkyl
phosphates (TBP and TEP) and dichloroaniline (DCA)
(see Appendix 3).
High levels of heavy metals - including chromium, copper
and nickel - were also found in the discharged wastewater.
These were predominantly bound to suspended
particulates in the wastewater. These findings suggest that
wastewater intermittently discharged from the Well Dyeing
facility via Pipe 1 is a source of chromium, copper, nickel
and, possibly, zinc to the receiving river system. These
metals are known to have uses in the textile-manufacturing
sector. They can have toxic effects, particularly at high
concentrations (see Appendix 3, box C).

Dumping in the dark
The Greenpeace sampling team observed the Well
Dyeing complex on numerous occasions. No effluent was
discharged from Pipe 1 during the daytime. When the
facility was visited at night, however, discharge of effluent
was observed. The sample was taken during the night,
when white and blue foam was floating on the Shiji River.
It is a cause for concern that the discharge of large
amounts of effluent (proven to contain hazardous
chemicals at the time of the sampling) was observed only
during the night, although it is not known if this practice
was intentional or not.
The practice of hiding discharge pipes and effluent has been
observed elsewhere in China as a way of making pollution
from wastewater discharges less likely to be discovered.56
Greenpeace’s concern is that monitoring by the regulatory
authorities is unlikely to be taking place during the night,
so that if there were to be a discharge of prohibited
substances, or of substances in excess of legal limits, it
would be unlikely to be discovered by the authorities. The
phenomenon of nighttime wastewater discharge therefore
increases the potential for illegal discharges.


© GREENPEACE / QIU BO

50

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

image At low tide, the
discharge pipes buried
deeply in the banks of the
Huangsha Channel are
revealed. Greenpeace
campaigners take samples
to investigate water
pollution.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

Box 2.2 Alkylphenols and their ethoxylates
Production and use

Hormone disruptors

Alkylphenols are a group of man-made chemicals that
are not produced by natural processes and hence never
occur in nature, other than as a result of human activity.
The most widely used are nonylphenols (NPs), and
octylphenols (OPs), which are manufactured for a
range of specialised industrial uses as well as to produce
alkylphenol ethoxylates (APEs). APEs are a group of
non-ionic surfactants; the most widely used APEs are
nonylphenol ethoxylates (NPEs) and, to a lesser extent,
octylphenol ethoxylates (OPEs). NPEs are used as
surfactants, emulsifiers, dispersants and wetting agents in
a variety of industrial and consumer applications including
textile manufacture and industrial detergents, with smaller
amounts used as textile and leather finishers and as
ingredients in pesticides, and water-based paints.57,58

The most widely recognised hazard associated with
NPs and OPs is their ability to mimic natural oestrogen
hormones. This can lead to altered sexual development
in some organisms, most notably the feminisation of
fish.73,74 Exposure to OPs caused adverse effects on male
and female reproductive systems in rodents, including
lower sperm production and an increase in sperm
abnormalities75,76,77, as well as DNA damage in human
lymphocytes78. Impacts on immune system cells in vitro
have also been described.79

Distribution and effects
These chemicals (especially NPs and their derivatives)
have become widely distributed in the environment;
once released to the environment, NPEs and OPEs can
degrade back respectively to NPs and OPs, which are
persistent, bioaccumulative and toxic to aquatic life59,60,61.
They are common contaminants of sewage effluents
and sludge62,63,64, which may be applied as fertilisers to
agricultural land. NPs have been detected in rain and
snow in Europe65,66, while residues of both NPs and OPs
have been reported as contaminants in house dust67,68,
and indoor air69,70. Both NPs and OPs are known to
accumulate in the tissues of fish and other organisms, and
to biomagnify through the food chain.71 NPs and OPs have
recently also been detected in human tissues.72

Existing controls
The manufacture, use and release of NPs, OPs and their
ethoxylates is not currently regulated in China. However,
NPs and NPEs have very recently been included on the
‘List of toxic chemicals severely restricted for import
and export in China’, which means that their import or
export now requires prior permission.80 Outside China,
regulations addressing the manufacture, use and release
of NPs, OPs and their ethoxylates do exist in some
regions, for example the EU.
In Europe, for most of their former uses APEs have now
been replaced by alcohol ethoxylates. In 1992 parties to
the OSPAR Convention81 decided to phase out NPEs in
cleaning agents, starting with use in household products.82
In 1998 the OSPAR Commission agreed on the target of
ending discharges, emissions and losses of all hazardous
substances to the marine environment by 2020. NPs and
NPEs were included on the first list of chemicals for priority
action towards achieving this target.83 NPs have also been
included as ‘priority hazardous substances’ under the EU
Water Framework Directive.84 Furthermore, within the EU,
products containing greater than 0.1% of NPs or NPEs
may no longer be placed on the market since January
2005, with some minor exceptions principally for ‘closedloop’ industrial systems.85

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

51

Conclusions
The investigations conducted by Greenpeace and the
evidence presented in this section have demonstrated
that two textile manufacturers have been polluting
the Yangtze and Pearl River deltas with hazardous
chemicals. It has been confirmed that these suppliers have
commercial relationships with a range of major brands,
including Abercrombie & Fitch, Adidas, Bauer Hockey,
Calvin Klein, Converse, Cortefiel, H&M, Lacoste,
Li Ning, Meters/bonwe, Nike, Phillips-Van Heusen
Corporation (PVH Corp), Puma and Youngor. These
suppliers have also been linked with many other Chinese
and international brands. The pollution of local water supplies
recorded at these facilities is occurring despite the fact that
some of the above-named brands have policy statements
that support the principle of zero emissions.
When confirming their commercial relationship with the
Youngor Group, Bauer Hockey, Converse, Cortefiel, H&M,
Nike and Puma informed Greenpeace that they make
no use of the wet processing of the Youngor Group for
the production of their garments. However, regardless of
what they use these facilities for, none of the brands found
to have commercial links with these two facilities have in
place comprehensive chemicals management policies
that would allow them to have a complete overview of
the hazardous chemicals used and released across their
entire supply chain, and to act on this information. As
brand owners, they are in the best position to influence the
environmental impacts of production and to work together
with their suppliers to eliminate the releases of all hazardous
chemicals from the production process and products.
Many of the substances identified in the wastewater
samples from the two facilities are soluble in water,
enabling them to remain relatively mobile within the river
systems to which they are released. This means they are
likely to be transported downstream, at which point it
would be impossible to trace them back to the source.
Some of these substances are known to be highly

52

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

persistent within aquatic environments and/or able to
accumulate within organisms. The ongoing release of such
substances is therefore likely to lead to ever-increasing
levels in the receiving environment, where in some cases
they will remain for a long period of time – even after
legislation may have prohibited their release.
The alkylphenols and perfluorinated chemicals found
in the samples are a cause for serious concern; these
substances are known hormone disruptors and can be
hazardous at very low levels. Not enough is known about
some of the other chemicals found, in terms of their toxicology
or their potential impacts following release to the environment.
However, in such cases the burden of proof should lie with the
polluter to prove that the substances released are safe, in line
with the precautionary principle that requires that action be
taken to prevent damage to the environment even when there
is scientific uncertainty (see Section 4).
Our investigations have also highlighted instances of the
composition of discharged wastewater varying significantly
over time, and of active discharge occurring sporadically
and during the night. Effectively monitoring discharges
from any facilities with either of these types of discharge
pattern would be extremely difficult.
As noted in Section 1, Chinese national and provincial
legislation does set controls on the discharge of certain
chemical pollutants in wastewater, including some of those
identified at the facilities we investigated; for example the
heavy metals chromium, copper and nickel. However, the
regulations do not absolutely prohibit the discharge of these
hazardous chemicals; rather, they set maximum permissible
levels for the substances listed. In other words, textile
complexes such as the two we investigated get a ‘licence to
pollute’ as a result of the current legislative system. What is
more, the regulations simply do not address the majority of
substances that we identified in wastewater.

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
two

image A young boy
stands in front of a
heavily polluted pond
in Gurao, Shantou,
where the economy
is centered around
textile production.

The use of ‘end-of-pipe’ measures, including conventional
wastewater treatment plants, cannot effectively
address the presence of many hazardous substances
in wastewater. In fact, our investigation showed that
investment in a modern wastewater treatment plant at the
Youngor Textile Complex has not prevented the release of
a range of complex organic chemicals.
Clearly, our investigations could not attempt to encompass
all sources of hazardous chemical discharges into the
Pearl River and Yangtze River deltas. However, the
documentation of hazardous chemicals discharged
in the wastewater from the two industrial complexes
investigated provides a clear indication of the potential for
discharges to occur at other textile facilities. The problem
requires much more extensive investigation, both by
government authorities and by companies outsourcing
their products – with a view to ending the discharge of
hazardous substances. Critical to this aim will be increased
transparency and disclosure of all releases of hazardous
chemicals from such facilities.
The following section analyses in more detail the way
in which responsibility for discharges of hazardous
substances extends down the supply chain, sets out the
need for clothing brands to assume their share of that
responsibility, and suggests how they might begin to go
about this.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

53

© GREENPEACE / LU quang

Greenpeace
International

03
54

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
three

03
The need for corporate
responsibility
The textile industry: a dirty past, a cleaner future?
The investigations outlined in Section 2
prove that hazardous chemicals have been
discharged from two major Chinese textilemanufacturing facilities. The connections
between these facilities and many major brands
that use them as suppliers have also been
highlighted.
The use of rivers as a dumping ground for wastewater
containing hazardous chemicals is likely to be common
across China, whether the wastewater is discharged
directly into a river untreated or after passing through a
wastewater treatment plant that cannot deal effectively
with persistent hazardous chemicals. However, China
is not the first place to suffer from textile industry
pollution of this kind.

© ROSE / GREENPEACE

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

55

Progress and pollution
The modern textile industry goes back to the 19th century,
with the mechanisation of spinning and weaving that
began in the UK and spread from there to the rest of
Europe and North America. Although the manufacture of
synthetic dyes was an important factor in the emergence
of the chemical industry at that time1, the growth in the use
of many of the more persistent hazardous chemicals in
the textile industry began after the Second World War;
for example:
• alkylphenols were first introduced into the UK in
the 1940s2;
• chlorinated flame retardants were first used on a
large scale during the Second World War for military
clothing, while brominated flame retardants were
commercialised in the 1950s3; and
• perfluorinated chemicals were first manufactured in
the 1940s4 but commercialised in the 1950s5.
Therefore, although the manufacture of these persistent
hazardous chemicals began before the Second World
War, the commercial use of such chemicals increased
greatly during the second half of the 20th century.

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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

The production of textiles for global markets began to
shift from North America and Western Europe to Asia in
the 1950s, due to lower production costs: first to Japan,
then to Hong Kong, Taiwan and Korea, which dominated
the textile and clothing export markets in the 1970s
and early 1980s. The most recent migration has been
mainly to Southern and Eastern China, starting in the late
1980s, as well as to Indonesia, Thailand, Malaysia, the
Philippines and Sri Lanka, with new suppliers in other
South Asian and Latin American countries entering the
market in the 1990s.6 The latest trend within China is the
transfer of textile industry clusters to Western and Central
China.7
It has been observed that the “success of the textile
industry in China illustrates both the globalisation of
an industry and the historic export of environmental
degradation by western nations to China.”8 It is
certainly the case that the textile industry has been
responsible for gross river pollution in the Global North in
the past. For example, in the north-eastern US, numerous
textile mills dumped wastewater from dyeing processes
directly into rivers.9

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
three

Shifts in the production of textiles for the global market

Figure 3.1: Production of
textiles for global markets
began to shift from North
America and Western
Europe to Asia from the
1950s onwards.

1950s WESTERN EUROPE
1980s KOREA

1950s NORTH AMERICA
PRESENT+1980s WESTERN CHINA

1960s JAPAN
1970s TAIWAN
1970s HONG KONG

PRESENT +1980s SOUTHERN CHINA
1990s THAILAND

PRESENT+1990s
THE PHILIPPINES

PRESENT+1990s SRI LANKA
PRESENT+1990s MALAYSIA

PRESENT+1990s INDONESIA

1990s SOUTH AMERICA

1950s
NORTH AMERICA
WESTERN EUROPE

1960s
JAPAN

1970s

1980s

1990s

PRESENT

TAIWAN

WESTERN CHINA

SRI LANKA

SRI LANKA

HONG KONG

SOUTHERN CHINA

MALAYSIA

MALAYSIA

THAILAND

THAILAND

INDONESIA

INDONESIA

THE PHILIPPINES

THE PHILIPPINES

SOUTH AMERICA

SOUTH AMERICA
WESTERN CHINA
SOUTHERN CHINA

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

57

The pressure to cut corners
© GREENPEACE / QIU BO

image Yellow wastewater
from ‘Pipe 1’ of the
Youngor textiles factory.

The role that stricter environmental controls in the Global
North played in the growth of the textile industry in China
has been relatively minor compared to other factors such
as the availability of cheap labour.10 However, when the
pressure to cut costs is overwhelming, in part due to
demand for cheap clothing from discount retail chains,
investment in measures to protect the environment is easily
bypassed. For example, it is reported that prices of clothing
imported to the US have fallen 25% in real terms since
199511, leading to a constant need to slash costs, which
in turn has encouraged some textile factories in China to
discharge wastewater directly into rivers. Treatment of
contaminated wastewater – which can address some types
of pollution, although ineffective against many persistent
hazardous substances (see Section 1) – costs around
$0.13 US dollars a tonne. Factories can increase profit
margins substantially by sending wastewater directly into
rivers, in violation of China’s water-pollution laws.12
Nevertheless, environmental costs can be overestimated
because it is assumed that ‘traditional’ pollution control
methods will be necessary. In North Carolina in the
1980s (see Box 3.1), the future of the textile industry was
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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

threatened by the prohibitive cost of treatment that would
remove alkylphenol ethoxylates (APEs) from wastewater
effectively enough to comply with environmental
standards. However, when the companies concerned
replaced APEs in their manufacturing process with safer
alternatives, these costs were avoided. As a result, the
North Carolina textile industry was able to continue into the
1990s, before eventually relocating to India and China.
Unfortunately, in the process of migrating to China,
India and other developing countries, the textile industry
continues to rely on persistent hazardous chemicals in its
processing, using wastewater treatment plants to treat
discharges or dumping waste directly into rivers, instead of
replacing these chemicals with safer alternatives, as was
the case in North America.
Despite the lesson from industrialised countries that the
use of many hazardous chemicals can be avoided in
textile processing, the concern is that they will continue
to be used in China and other countries where the textile
industry is expanding, such as India, Pakistan, Vietnam,
Cambodia and Bangladesh.13

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
three

Tracing the threads of responsibility
Textile and clothing product chains can be long and
complex; the various steps of textile processing and
garment manufacture take place in many different
countries around the globe. The global textile and
garment market is currently worth more than $400bn US
dollars a year; it is predicted to grow by 25% by 2020,
with much of this growth coming from Asia.14 China
ranks second in the world for annual textile exports with
28% of the market (just behind the EU with 30%); it is
first in the world for clothing exports, with 34% of the
market15. Taking the two sectors together, China has
been the world’s leading exporter of textiles and
clothing since 199516. The EU, the US, India, Turkey,
Pakistan, Indonesia, Thailand and Vietnam all rank
among the top 15 exporters of textiles and clothing,
according to WTO trade statistics.17

The major actors in the textile and clothing supply chain
are multinational brand owners, raw materials suppliers,
textile and clothing producers, financiers, retailers and
customers. Companies are sometimes responsible
for more than one link in the supply chain task: for
example, the brand owner and retailer may be the same
company, or the brand owner may have its own in-house
production chain. Brand owners may contract suppliers
directly or indirectly, through agents or importers.
Normally, it is the brand owner that triggers the
product development process, including research
and design.18 Brand owners are therefore the
best placed actors to bring about change in the
industry.19

The businesses involved in the textile and clothing supply chain20
Figure 3.2 shows
the main actors
involved in the textile
and clothing supply
chain, apart from the
brand owners.

Chemical industry

Multinational chemical
industry and/or local
suppliers provide dye-stuff
and chemical inputs

Man-made
fibres

Yarn
formation
fibre preparation
texturising
■ spinning

Fabric
formation
warping
slashing
■ weaving
■ knitting









Natural
fibres

Wet
processing
■ preparation
■ dyeing
■ finshing
■ printing

Textile producers

Fabrication



cutting
sewing

Clothing
manufacturers

Products

Clothing
retailers

Traders, merchants & agents involved at various stages

Farmers and growers
Multinational chemical industry and/or local suppliers - pesticides, fertilisers and seeds

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

59

While developing countries produce half of the world’s
textile exports and nearly three-quarters of the world’s
clothing exports21, the majority of the major clothing
brands are based in the Global North. Market-leading
clothing and footwear brands globally include H&M, Nike,
Agiocur (Inditex) Zara, C&A and Adidas22, while major US
clothing manufacturers include Levi Strauss, Phillips-Van
Heusen, VF Corporation and Warnaco23. In general, the
textile and clothing industry is highly fragmented, with the
involvement of many different brands – in the US, the 50
largest brands generated less than 40% of revenue24, while
in the EU more than 60 companies generate about 25%
of revenue25.
The complexities of the supply chain inevitably make
for a lack of transparency about the various steps
involved in the manufacture of products and the potential
environmental impacts.

© ROSE / GREENPEACE

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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

The actor in a position to demand all information on
the various supply chain steps is the brand owner,
although manufacturers and trade agents can also
take a co-ordinating role.26 However, brands do not
usually disclose details of all their suppliers, in particular
subcontractors or those several steps down the supply
chain. To complicate the situation further, suppliers often
contract with more than one brand, and contracts can
be short-term as a result of short product cycles and
volatile trends.
This report focuses on wet processing, including dyeing,
finishing and printing. Of all of the finishing operations, this
is where the majority of hazardous substances are used
and discharged to surface water.27 The responsibility
for pollution from wet processing lies both with the
textile producers themselves and with the brands
that they supply with their products.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Section
three

Sportswear companies – influential players
Section 2 outlined the links between a number of leading
clothing brands and two Chinese textile manufacturing
facilities that have been found to be discharging a range
of hazardous chemicals. This is despite the fact that many
of these brands have already developed Corporate Social
Responsibility programmes that include restrictions on
certain hazardous chemicals and supply chain standards.
Although the textiles and clothing industry is heavily
fragmented, the sportswear brands stand out as
influential players who are well positioned to act as
leaders in the shift towards a toxic-free future, due in
part to their track-record of innovation in the sector.
The sportswear brands with connections to the
manufacturing plants outlined in Section 2 are the
international brands Adidas, Nike, Puma, Bauer
Hockey and Converse (a Nike brand), together with
the Chinese sportswear brand Li Ning. Paradoxically,
while many of these sportswear brands often promote
themselves as champions of healthy lifestyles, at
present they lack the policies and systems to ensure
that hazardous chemicals are not released into the
environment during production. What many of these
brands do have in place, however, is a system of
preferred suppliers where long-term relationships are
cultivated and privileges are given to selected suppliers.
This system has the potential to act as an ideal platform
through which to develop collaborative policies and onthe-ground action to eliminate the use of toxic chemicals
during the production process.
The sportswear brands are some of the largest within
the whole clothing sector. In Europe, for example, Nike
is the second biggest single brand and Adidas is also
a major player – particularly when its Reebok brand is
included – putting it on a par with market leader H&M.
Also important, but with a smaller market share, is Puma.28

Within the global sportswear sector, Nike and Adidas have
the biggest share of the sports clothing market, at 7% and
6% respectively, with Puma at 2%; however, these three
companies combined make up over half of the global
sports footwear market, with Nike leading on 31%, Adidas/
Reebok on 22% and Puma on 7% (see Appendix 1).29,30
Historically, Nike was the first major sportswear company
to shift its production to Asia; by the early 1980s it had
closed its US factories and was sourcing almost all of its
production from Asia, initially from Taiwan and Korea. As
costs rose in these countries, Nike urged its suppliers to
relocate to other, lower-cost countries such as Indonesia,
China and Vietnam.31 Adidas shifted production to Asia32
at the end of the 1980s33 and Puma not till the 1990s34.
All three companies aroused controversy by sourcing
products from factories and countries where low wages,
poor working conditions and human rights problems were
rampant.35 Indeed, concerns about the right to freedom of
association continue to this day.36
Subsequently, in response to consumer pressure, all three
companies developed basic labour and environmental
health standards. Since then they have implemented
Corporate Social Responsibility (CSR) programmes
and in recent years have become recognised as
leaders on many sustainability-related issues; for
example, they make up three of the six companies listed as
sustainability leaders in the Dow Jones World Sustainability
Index 2010 for the clothing, accessories and footwear,
with Puma being the Industry Leader for the sector.37,38
However, despite sophisticated CSR and supply
chain management systems, these companies have
yet to take corporate responsibility for the hazardous
substances discharged in wastewater
by their suppliers.

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61

Hazardous substances in wastewater
– a corporate blind spot
There are large differences in the way the clothing
brands highlighted in this report approach the issue of
hazardous waste. Some – such as sportswear brands Li
Ning and Bauer Hockey, as well as fashion brands such
as Youngor and Abercrombie & Fitch – do not publish
a chemicals management policy or a list of chemicals
that are banned or restricted in their products or in their
manufacture (restricted substances list (RSL)).
In contrast, Nike, Adidas and Puma all publish CSR
information and have a relatively sophisticated approach
to managing hazardous substances in their products,
with detailed RSLs specifying which substances must not
be present, above certain specified limits.39,40,41 There are
also bans or restrictions on the use of certain hazardous
substances in the manufacturing process, although these
are usually far more limited in scope. All three companies
have programmes to ensure that their suppliers
implement their RSLs, with product testing procedures
to ensure compliance. However, programmes to address
wastewater discharges are not clearly linked with the
RSLs, but are intended mostly to ensure compliance with

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Notably, there is no evidence that any of the three
aforementioned brands implement measures to
restrict the release of most hazardous substances
into water via their suppliers’ wastewater discharges.
This is despite the fact that they all have policy statements
supporting the elimination of toxic emissions (which must
logically include emissions to water) throughout a product’s
life cycle to a greater or lesser extent.
Nike’s ‘North Star’ concept, was developed to “define
what sustainable products and a sustainable company
would look like”. “Healthy Chemistry”, with the objective
being to “minimise the impact of product ingredients
throughout the life cycle”, is a key part of this, as is “Water
Stewardship”, where Nike’s aim is to “collaborate with
factories to improve efficiency in order to avoid borrowing
more water than is needed and to be able to return it as
clean, or cleaner, than it was found”.43

© ROSE / GREENPEACE

© ROSE / GREENPEACE

© ROSE / GREENPEACE

62

local laws or the brands’ own very general water
pollution parameters.42

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

However, there is no publicly available information
about the measures that Nike takes to guarantee
that this objective will be implemented in practice.
Key information, such as the company’s suppliers
guide and data on its water program, is not publicly
accessible. This is despite the fact that Nike’s
chemicals programme has some progressive
elements, such as its use of the ‘Principles of Green
Chemistry’ as an approach for replacing hazardous
substances.44
Adidas’s Environmental Strategy is to “manage
environmental effects throughout the value chain.
The focus will always be on the following:
• Sustainable use of resources
• Avoidance of and reduction in emissions
• Limiting risks and chemical hazards.”45
Under the heading ‘Green Company’ on its website46,
Adidas also states that “Our strategy is to become a
zero-emissions company by:

Section
three

Despite a relatively sophisticated system of supply
chain management, including auditing and third party
verification, Adidas’s overall approach lacks detail on
hazardous substances. For example, there are no clear
criteria for the selection of hazardous substances to be
prioritised for phase-out, with clear target dates. Some
hazardous substances are already restricted in products,
but although Adidas does require its suppliers to avoid
the use of the substances listed in its RSL, there is no
implementation plan on how to achieve this, apart from
some limits on the discharge of heavy metals.48
Puma’s overall approach to sustainability is to “drive
our business towards cleaner, greener, safer and more
sustainable systems and practices”.49 More specifically, it
states “Factories are responsible for ‘harmful substances
free’ production. Factories will be held responsible and
liable for all loss and damage suffered by PUMA, should
any hazardous substances be found in the materials,
components or final products.”50

“Harmful substances free production” appears to refer
to the manufacturing process and emissions from it;
• Embedding environmental best practice in
however, in Puma’s ‘Handbook on Environmental
everything we do 
Standards’51 the use and emission of hazardous
• Maximising environmental efficiency gains 
substances is not addressed among the specific steps
• Supporting and harnessing our people’s passion for to be taken to reduce and prevent environmental impact.
Hazardous substances are considered when they are
a greener planet.”
found in materials, components or final products, but not
However, the use of the term ‘zero emissions’ is
when released to the environment, with little attention
misleading, as the strategy is focused only on the firm’s
given to production-related environmental standards.
own production sites and does not include its supply
chain. Nor is the elimination of discharges of hazardous
substances mentioned among the strategy’s targets.
The targets that are mentioned, such as cutting
‘relative’47 energy use and reducing paper use, are
unambitious.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

63

Two examples of how the companies perform
The table below shows the restrictions (or lack of them)
that each company imposes on the use of alkylphenols,
their ethoxylates and two perfluorinated chemicals (PFCs),
perfluorooctane sulphonate (PFOS) and perfluorooctanoic
acid (PFOA). These substances are restricted in products
partly as a response to legislation, such as the prohibition of
the use of nonylphenol ethoxylates (NPEs) and nonylphenols
(NPs) within the EU. Both Nike and Adidas go beyond the
regulatory requirements with their restriction on PFOA,
applying the same legal limit as is used for PFOS.

However, none of the firms give any information about
whether they restrict the use of any of these substances
in manufacturing processes52, and no limits for their
wastewater discharge are specified. This is despite the fact
that some alkylphenols are listed as priority substances in
the EU Water Framework Directive (see Section 2, Box 2.2).
In fact, as the investigation presented in Section 2 has
revealed, limits on the concentration of a substance in the
final product do not prevent its discharge in wastewater of
the brands’ suppliers.

How far do the brands’ restrictions on alkylphenols, PFOS and PFOA go?
Scope of restriction

Alkylphenols and ethyoxylates**

PFOS**

PFOA

Nike53

Product
Manufacturing
Wastewater

yes
no
no

“Additional chemicals of concern”
for future restriction*

Yes – limit of
1μg/m2

Yes – limit of
1μg/m2

Adidas54

Product
Manufacturing
Wastewater

yes
no
no

Sum of NP, OP and NPE is 1000 ppm; Yes – limit of
100 ppm for NP as single parameter*** 1μg/m2

Yes – limit of
1μg/m2

Puma55

Product
Manufacturing
Wastewater

yes
no
no

sum of NP, NPE, APE, OP does not
exceed 1,000 mg/kg***

Yes – 1μg/m2

No

Li Ning

Product
Manufacturing
Wastewater

no
no
no

No

No

No

* In Nike’s list of restricted substances for finished products. APEs (NPs, NPEs, OPs, OPEs) are on Nike’s list of ‘Additional Chemicals of Concern’:
“These chemicals are currently the focus of governmental, academic, or NGO research and may in the future be legally regulated or appear on the Nike
RSL.” Suppliers are asked to determine whether these substances are used, state what their function is, and avoid them if possible. However, there is no
evidence as to how this very weak requirement is to be implemented, or whether discharge to wastewater is considered.
** Restricted by legislation56
*** NP = nonylphenols, OP = octylphenols, APE = alkylphenol ethoxylates, NPE = nonylphenol ethoxylates

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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Table The restrictions
(or lack of them) that
companies impose on the
use of alkylphenols, their
ethoxylates and two types
of PFCs.

Dirty Laundry
Unravelling the corporate
connections to toxic water
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Section
three

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© ROSE / GREENPEACE

Greenpeace
International

65

Shining the spotlight up the pipe

66

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© ROSE / GREENPEACE

Until now, the problem of water pollution as a result
of the persistent hazardous substances discharged
by their suppliers has been mostly out of sight and
out of mind. The lack of strong legislation, monitoring and
enforcement in the Global South, and in China in particular,
makes it difficult to deal with the discharge of hazardous
substances into water effectively. The brands need to take
the lead by accepting responsibility for the problem and
implementing a series of targeted measures throughout
their supply chains, going well beyond the general
‘environmental management’ approach.

© ROSE / GREENPEACE

The effort and attention of the aforementioned brands
is focused almost entirely on the final product and the
demands of their consumers. All of the companies
take rigorous steps through testing and verification
programmes to avoid a consumer product scandal.

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Unravelling the corporate
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Section
three

The need to claim responsibility:
lessons from the electronics sector
Responsibility for a product should not be limited to its
use as a consumer item; corporations that claim to take
responsibility for the whole life cycle of their products must
consider the use and emission of hazardous substances
at each stage. The manufacturing process is a major
part of this life cycle and it is unacceptable to overlook
the discharge of hazardous substances into water.
Brand owners are in the best position to influence
the environmental impacts of production, not only
through the suppliers they choose but also through
the design of their products and the control they can
exert over the use of chemicals in processing and in
the final product.
The experience of another sector in dealing with
environmental problems at a different stage of a product’s
life cycle – the end-of-life phase – may provide some useful
lessons. In recent years the electronics industry has taken
action at two stages of the product life cycle – design and
disposal – to reduce the emission of hazardous chemicals
from disposal or recycling of obsolete products (known
as electronic waste or e-waste). Efforts were focused on
reducing the use of brominated flame retardants (BFRs)
and the plastic polyvinyl chloride (PVC); the presence of
these substances in e-waste results in large amounts
of toxic by-products being released during ‘informal
recycling’, a common practice in countries such as
China and India. These releases in turn harm the local

environment and the health of recycling workers.
Firstly, many brands redesigned their electronics products
to eliminate the use of these hazardous substances.57
Market leaders such as Nokia, Sony Ericsson and Apple
have already phased them out from their product ranges; it
is predicted that over 50% of the market for mobile phones
and PCs will be PVC and BFR-free by 2012.58 These
actions go much further than the requirements of EU
legislation to restrict hazardous substances in electronics,
which does not yet restrict either BFRs or PVC.59
Secondly, many multinational electronics brands have also
adopted take-back programmes for their own brand’s
e-waste in countries where their products are sold, and
where take-back legislation (such as the EU Directive
on Waste Electrical and Electronic Equipment60) does
not currently exist. This initiative follows Greenpeace
campaigns for brands to adopt and implement Individual
Producer Responsibility61 worldwide.
These examples demonstrate that voluntary action
by corporate brands to take responsibility for the
environmental impact of their products is feasible, as well
as being necessary in advance of legislation. Voluntary
action is especially important in countries where legislation
is unlikely to be enforced in the near future, or where it
does not go far enough. Voluntary action highlights the
need for legislation to level the playing field and in turn
influences the development of legislation, by showing the
feasibility of steps such as the phasing out of hazardous
substances.
Larger brands, whether in electronics, textiles or
any other sector, can and often do exert an
enormous amount of pressure on their suppliers
to achieve high standards and provide adequate
information. Restricting and requiring information
on the use of hazardous substances in a supplier’s
facility, and their release to the environment, should
be just as much part of corporate responsibility
as restriction and information on the use of such
substances in products.

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Not in my backyard: phasing out
hazardous substances in the Global North
Although the majority of global textile production has
shifted to China and other emerging economies, some
remains in the Global North. The EU, the US and Canada
are still leading exporters of textiles.62 Yet regulations and
pollution prevention programmes mean that discharges of
certain hazardous substances by the textile industry are no
longer a severe problem in these countries.
For example, the use of NPEs in the Canadian textile
industry has decreased significantly since they were
declared toxic under national regulations: in 2006 it was
reported that the majority of textile mills had reached
a 97% reduction target established by Environment
Canada (the state environmental protection agency).63
Remaining uses were primarily in oils for knitting and
hosiery production equipment.64 The largest Canadian
manufacturer of furniture fabric and stretch knitted fabric,
Hafner Inc, reduced its discharges from 6,800 kilograms in
2001 to 68 kilograms in 2003, and as a result also cut the
chemical oxygen demand of its wastewater in half, which
reduced its annual effluent disposal costs by $15,000.65
There are also examples from the US of the replacement
of hazardous alkylphenols with safer alternatives leading
not only to reduced discharges of alkylphenols, but also
to financial savings in wastewater treatment, and even
helping the industry to survive – see Box 3.1 about the
textile industry in North Carolina.
While these examples show that the textile manufacturing
industry has reduced its use of hazardous substances
in the Global North, some producers of chemicals are
relocating to the Global South. For instance, the rising
cost of disposing of hazardous organic wastes from
dyestuff manufacture is an important factor that has led
international producers to shift production to southeast
Asian countries and China over the last two decades.66

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Box 3.1 Hazardous substance
phase-out: a win-win scenario
In the 1980s, a large proportion of the discharges
sent to publicly owned wastewater treatment plants
in North Carolina came from a thriving textile industry
that has now relocated to India and China. Because of
the toxicity of the industry’s discharges, the treatment
plants were failing toxicity tests and experiencing
difficulties in processing waste, with the costs payable
by the polluters.
The State’s Pollution Prevention Pays programme67
identified the source of the problem as APEs, in
particular the subclass NPEs.68 Linear alcohol
ethoxylates (LAEs) can perform the same function and
are less toxic, but had not been adopted by textile
companies because they cost about 30% more.
At first69 attempts were made to tackle the discharges
at the treatment plants through extended aeration
treatment, then with activated carbon. But these
expensive approaches failed to prevent the pollution.
The programme then demonstrated that replacing
APEs and NPEs with LAEs could solve the problem
of toxic discharges. Textile companies promptly
switched to LAEs, and the treatment plants began
passing their toxicity tests. This kept stakeholders
out of costly litigation, while improving environmental
quality.70
If the substitution approach had not been
adopted, “the level of treatment required would
have been so costly that the companies would
not have been able to stay in business.”71 As a
result of the successful substitution, over 100
companies remained in operation for more than
a decade.72

Greenpeace
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Section
three

Sticking around: the continued
production and use of PFCs
Whereas the replacement of alkylphenols in the textile
industry has been demonstrated by textile manufacturers
in a number of different countries in the Global North, the
picture with PFCs is not so simple. These substances
are best known for their use as non-stick coatings
for cookware, but their properties are also useful for
waterproof clothing.
Following a series of discoveries about the persistence,
toxicity and environmental distribution of PFCs in the
1990s73, 3M, the US manufacturer of PFOS (the most
problematic of the PFCs) voluntarily stopped its production
in 2000 – albeit after pressure from the US Environmental
Protection Agency. It also stopped production of PFOA,
having formerly sold the production rights to DuPont.74 In
2006, again under pressure from the EPA, DuPont and
other companies promised to phase out production of
PFOA by 2015.75 In contrast, it has been reported that
production of PFOS in China has increased in recent years,
with large-scale production beginning in 2003 and rising to
over 200 tonnes per annum in 2006.76
Despite the concerns about their persistence and toxicity,
increasing quantities of PFCs are being produced globally
– around 10,000 tonnes annually, half of which is used
for the impregnation of consumer textile products such
as all-weather clothing, carpets and upholstery.77 So
although the use of PFOS and PFOA in textiles appears
to be declining, the use of PFCs generally is increasing.78
However, other PFCs may act as sources of PFOS and
PFOA, leading to continued release of these substances to
the environment.79

By the time the European Commission proposed controls
on PFOS in 2005, most of the major uses which it
suggested for prohibition had already been discontinued
in Europe, including its use in carpets, upholstery, other
textiles and leather, and paper and cardboard packaging
products.80,81 The former users of PFOS and PFOA have
now shifted towards alternative PFC substances which are
not as hazardous or persistent, although their toxicity and
environmental impact still need to be examined.82
For example, according to the German Textile Finishing
Alliance, PFOS and PFOA are no longer used for textile
finishing in Germany; alternative PFCs (fluorocarbon
polymers) are used, though these can contain small
quantities of PFOA.83 The German Textile Chemicals
Association estimates that German companies use about
1,000 tonnes a year of formulations that contain 20% to
30% of fluorocarbons, with good formulations containing
less than 1 part per million of PFOA.84
Non-PFC alternatives, such as fluorine-free impregnation
products for textiles85, are also available, but there is again
a lack of toxicological information about these substitutes
and limited information about companies implementing
them. The Norwegian sporting goods company Helly
Hansen stated in 2008 that from summer 2009 at the
latest all its products would be free of PFCs.86,87

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Hazardous residues in products
Clearly, the international brands highlighted in this
report are largely focusing on their products rather
than on other sources of release, such as their
suppliers’ wastewater discharges. Nevertheless,
as long as hazardous chemicals are being used,
products are still likely to contain residues.
In 2006, Friends of the Earth Norway conducted tests on
all-weather jackets for children, to confirm their suspicion
that they were impregnated with fluorinated compounds
despite the availability of more environmentally friendly
impregnation products. Six jackets from five different
brands were bought in the Nordic countries and
investigated for fluorinated substances: a number of
unbound fluorinated compounds were found, with levels
for PFOS-related compounds at between <5 and
100μg/m2 88 , well above the EU legislative limit of 1μg/m2
in some cases.

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Despite the use of NPEs and NPs being prohibited in
the EU, NPs are still being found in the sludge of EU
wastewater treatment plants and in discharged treated
wastewater.89 Because legislation does not control the
import of textiles and clothes containing NPEs, these
substances can be released into wastewater during
washing. Two studies of products in Sweden, one on hand
towels and one on T-shirts, confirmed that they contained
NPEs; in T-shirts, the levels were generally highest in
garments produced outside the EU, particularly in Turkey
and China. If the towels and T-shirts are representative,
it is estimated that in 2006 about 46 tonnes of NPs were
imported into Sweden in textile products and that the
majority of this total ended up in the wastewater network.90
The study on T-shirts emphasised that the quantity of
NPEs found in the product does not reflect the quantity of
chemicals used in the manufacturing process, but rather
how well the fabric was rinsed before it was made into an
item of clothing. We should not have to choose between
NP pollution in EU wastewater treatment systems on
the one hand, and even greater discharges of NPs from
manufacturing facilities into rivers in China and other
developing countries on the other.

Greenpeace
International

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Unravelling the corporate
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Section
three

Conclusion
When a less hazardous substitute is available and already
being used by the textile industry in some locations,
substances such as NPs should not be used in textile
manufacturing anywhere in the world. However, given the
major differences in regulations and enforcement from
country to country – and particularly between advanced
and emerging economies and developing countries –
achieving this objective by legislative means could be a
slow and difficult process.
On the other hand, multinational corporations
such as the brands highlighted in this report have
the power to persuade their suppliers to phase
out these substances. This goal is achievable in the
short term, until legislative changes can catch up. The
feasibility of rapid change in an industrial sector has been
demonstrated by companies in the electronics industry
with the phase-out of PVC and BFRs in their products,
currently being implemented through their supply chains.91
Until recently, many in that industry would have considered
this development impossible; in fact, the availability of
substitutes has increased in response to demand from the
electronics brands.92

There is a need for rapid intervention to instigate a global
phase-out of hazardous chemicals, starting with some
that have already been regulated in certain markets (see
Section 4 for a list of 11 priority chemicals for phase-out).
Owing to their market share and high profile sportswear
brands are in a unique position to take a lead within
the textile industry, setting a deadline and developing a
substitution plan. Provided that enough resources are
used to develop alternatives, substitutes will begin to
emerge.
However, the need to take action on this issue is not limited
to the brands outlined in this report. All clothing brands
have a duty to influence their supply chains to phase out
the use and discharge of hazardous substances.
Section 4 outlines the steps needed for both companies
and governments to implement this phase out plan.

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71

03
04
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Section
four

04
Championing a toxic-free
future: Prospects and
recommendations
A turning point for the textile industry
Greenpeace investigations have revealed
that two textile manufacturers have been
discharging persistent and hazardous
chemicals into rivers in China. Whilst the
findings documented in this report offer a
snapshot of the kind of toxic chemicals being
released into our waterways, such discharges
are likely to be the tip of the iceberg, given the
scale of the textile manufacturing industry in
China and elsewhere.
Our investigations have also linked the two facilities
involved with several major brands, including sportswear
companies, other clothing brands and retailers. Notably,
the international brands Abercrombie & Fitch,
Adidas, Bauer Hockey, Calvin Klein, Converse,
Cortefiel, H&M, Lacoste, Nike, Phillips-Van Heusen
Corporation (PVH Corp) and Puma, and the Chinese
brands Li Ning, Meters/bonwe and Youngor, have
all had products manufactured at one or the other of
the facilities.
The textile industry is playing an important role in the
industrialisation and development of many countries in
the Global South, China in particular. Major brands with
supply chains in these countries are in a unique position
to work with their commercial partners to reduce the
environmental impacts of textile manufacturing, and in
the process help lead the shift away from hazardous and
environmentally damaging chemicals, which needs to
happen across all industries.

Just as some electronics brands have recently taken
the lead by phasing out hazardous substances in their
products, so the major clothing brands must now take
responsibility for ensuring that their suppliers phase out
the use and discharge of hazardous substances during
the wet processing of textiles – where many hazardous
substances are used and discharged into water. Part of
a company’s responsibility is to tackle the discharge of
persistent hazardous chemicals and to avoid the serious
and often far-reaching impacts these hazardous chemicals
can have on the environment and on people’s livelihoods.
However, to respond to this challenge effectively, a change
in our whole approach to the problem of water pollution
is needed. As our investigations have shown, modern
wastewater treatment plants do not prevent the discharge
of some hazardous, persistent chemicals into our
waterways. A new strategy is therefore needed to prevent
such chemicals being used in the first place, bringing
about an end to their use altogether and their replacement
with non-hazardous alternatives.

The role of brands:

© SJOLANDER / GREENPEACE

Brands have a pivotal role to play when tackling the use
and release of hazardous chemicals. Their influence
extends beyond the direct use of hazardous chemicals
in their products to their use and discharge in production
processes, including the various stages of their supply
chain. In other words, brands have the means to act
immediately to eliminate the release of hazardous
chemicals by working together with their suppliers and
requiring that their long-term commercial partners are
leading the shift from hazardous to non-hazardous
chemicals.

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73

To this end, Greenpeace is calling on the brands and
the suppliers identified in this investigation to become
champions for a toxic-free future, by eliminating
all releases and uses of hazardous chemicals from
across their supply chains and products.
Specifically, this entails establishing clear company and
supplier policies that commit their entire supply chain to
shift from hazardous to safer chemicals, accompanied
by a plan of action that is matched with clear and realistic
timelines.
Proper policies to eliminate the releases of all
hazardous chemicals across a company’s entire
supply chain should be based on a precautionary
approach to chemicals management (see Box 4.1),
and account for the whole product lifecycle and releases
via all pathways. To be credible, these policies need to
be accompanied by a plan of implementation, with clear
timelines, and be matched with real and substantial
action on the ground.
Knowing what hazardous chemicals their suppliers use
and release – and making this data publicly available – will
be fundamental to the brands’ shift towards championing

a toxic-free future (see Box 4.2). Transparency will also be
crucial with regard to showing progress made to eliminate
the release and use of hazardous chemicals.
Due to the urgency of the situation, brands need to work
quickly to identify the most dangerous chemicals and
eliminate these as a priority. Full public accountability for, and
disclosure of, what they and their suppliers are discharging
into public waterways will play a key role in this work.
Above all, these brands need to act as leaders and
innovators. The problems associated with the use and
release of hazardous chemicals within the textile industry
will not be fixed by severing ties with one or two polluting
suppliers. The solutions are to be found in working
together with their suppliers to bring about systematic
change in the way brands and businesses create their
products. Such action requires vision, commitment and a
desire to improve upon the current approach to hazardous
chemicals. Every brand and supplier has the responsibility
to know when and where hazardous chemicals are being
used and released up and down their supply chain and
to strive to eliminate them. It will therefore be through
their actions, not their words, that these brands can
become agents of positive change.
© ROSE / GREENPEACE

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International

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Section
four

Box 4.1 The precautionary principle and precautionary action
Experiences such as the pollution of the Great Lakes
- where it took scientists more than 50 years to fully
comprehend the impacts on human health and wildlife
of persistent chemicals such as the organochlorines2 drove the shift to replace the failed assimilative capacity
approach to pollution (based on the assumption that
hazardous substances can be absorbed and diluted to
harmless levels) with the precautionary principle, as laid
down in the Rio Declaration.3 The precautionary principle is
based on the assumption that some hazardous substances
cannot be rendered harmless by the receiving environment
and that prevention of potentially serious or irreversible
damage is required, even in the absence of full scientific
certainty.
The precautionary principle can be defined in terms of four
elements :
1) Serious or irreversible damage to ecosystems must be
avoided in advance, both by preventing harm and by
avoiding the potential for future harm.
2) High-quality scientific research must be employed
as a key mechanism for early detection of actual and
potential impacts.
3) Action to protect ecosystems is necessary, not simply
possible, even in the presence of uncertainty, ignorance
and indeterminate outcomes.

In policies and practice these principles can be translated
into the following:
1) P
 reventive action must be taken (as opposed to
attempted control of pollution through allowable
emission levels).
2) T
 he preventive action should be taken promptly, rather
than waiting for conclusive scientific proof of a causeeffect relationship, at which time it may be too late (and
lead to the incurrence of environmental, human health
and financial damage and remediation costs).
3) Prevention should be implemented through substitution
(replacement of the hazardous chemical by alternative
substances, materials, technologies and/or techniques).
4) Precaution requires reversal of the burden of proof
(ie making the party proposing the release of a substance
responsible for demonstrating that it is unlikely to cause
harm, rather than the opponent being responsible for
proving that a release is likely to cause harm).
For action to be truly precautionary, it must ensure that
the fundamental objective – to reduce the overall chemical
burden – is observed. To this end, it must recognise that
the decision to prevent the discharge of a certain chemical
may require a fundamental re-evaluation of the need for a
product or process, and may not always imply simple
substitution with an alternative.

4) All future technical, social and economic developments
should implement a progressive reduction in
environmental burden.

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image A resident
of Gaoping village
in Sanjiao Town,
Zhongshan City , sits on
a tree by the river. On the
opposite bank, they are
busy building another
new factory..

Box 4.2 The right to know
about chemicals
The ‘right to know’ in the context of workplace and
community environmental law, is a term commonly used
to refer to the legal principle (or recognition of this principle)
whereby the individual has the right to know about the
environmental hazards - including chemicals - to which
they may be exposed in their daily life.
More specifically, community right-to-know aims to allow
members of the public greater access to environmental
information held by companies or public authorities, thereby
increasing the transparency and accountability of both.
Public access to information and public participation
in decision-making are essential to the push for clean
production systems free of hazardous chemicals.
Producers and product designers are made more
accountable when communities and workers can find out
what an industry is emitting into the environment or when
consumers can find out what is in a product.
One way of providing information to the public is to
establish pollutant release and transfer registers (PRTRs).
PRTRs are based on reported quantities of releases of
hazardous chemicals to the environment, facility by facility,
year by year, ideally made available in a searchable online
database. The Japanese PRTR, which was introduced in
2001 and covers 462 designated chemical substances
(Class I) in 23 sectors and 34,830 facilities, shows a
reduction of 24.5% in total annual releases (and waste
transfers) of hazardous substances between 2001 and
2008. Equally revealing is that no significant reduction was
observed for those industrial facilities releasing smaller
quantities of designated chemical substances (Class II),
which are not required to disclose their releases publicly
(merely to maintain data sheets).4
Willingness on the part of companies and facilities to
undertake full voluntary disclosure of releases and
transfers is an essential element to build up authorities’
willingness to implement such projects; and these can later
form the basis of right-to-know policies and laws.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QIU BO

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Section
four

The need for government action:

To this end, Greenpeace is calling for governments
to adopt a political commitment to zero discharge7
Leading brands and product manufacturers are in a
of all hazardous substances within one generation8,
position to take immediate steps to eliminate hazardous
based on the precautionary principle and a
chemicals. In order for this shift to be enforced
preventive approach to chemicals management,
throughout the industry and to reduce the risk of rogue
with the substitution principle at its core and producer
companies continuing to pollute, it is also necessary for
responsibility9 to drive elimination of hazardous
governments to put in place comprehensive chemical
substances.
management policies. Legislative measures can
To implement this commitment, policies and plans are
strengthen company policies by ensuring that they evolve
needed that establish a dynamic10 priority hazardous
as new information on hazardous chemicals becomes
substance list11 (to be acted on immediately), intermediate
available. Legislation also creates a level playing field,
enabling safer alternatives to gain a stronger foothold in the targets to meet the one generation goal and a publicly
available register of data about discharges, emissions and
market, which in turn makes them more cost-effective.
losses of hazardous substances.
The most effective strategy is therefore to prevent the
Governments, as well as all brands and suppliers, should
release of hazardous chemicals through eliminating use
embark on the steps outlined above as a matter of
at source – and, as already noted, brands are best placed
urgency, beginning with a commitment to zero discharges
to take immediate action. In recognition of this, policy
of hazardous chemicals and a plan to implement this. It is
makers are taking the approach of increasing producer
still possible to prevent further damage to the environment
responsibility, shifting the burden of proof of safety and
and the risk to populations from hazardous and persistent
the responsibility to provide information on the impacts of
chemicals, and to avert the need for costly clean-ups, but
hazardous chemicals away from governments and wider
action needs to be taken now.
society and towards those who make and sell chemicals
and the businesses that use these chemicals in their
products and manufacturing processes.5
In the EU, the responsibility for information on the hazards
of chemicals used for production and in products has now
been placed with chemical producers and manufacturers
of products containing chemicals.6 All companies (both
manufacturers and brands) therefore need to be fully
aware of the chemicals used by their suppliers, their
presence in products, their impacts and any discharges;
including those into water.
Starting from this principle of producer responsibility,
comprehensive chemicals management frameworks
should be devised as a matter of urgency, to prevent
ongoing releases into the environment that may require
future clean-up and have serious impacts on the
environment and on people’s health and livelihoods,
especially in the Global South.

The role of global citizens:

As global citizens, we can collectively influence brands to
act responsibly on behalf of the planet and its people. The
need for companies to make the right choices and protect
future generations has never been greater than it is today.
Please join with us and support Greenpeace in calling on
these brands to champion a post-toxic world – where
our water supplies are no longer polluted with hazardous,
persistent and hormone-disrupting chemicals by industry.
Together we can demand that they act NOW to detox our
rivers, detox our planet and, ultimately, detox our future.
A post-toxic world is not only desirable, it’s possible.
Together we can create it.

The time to act is now.
www.greenpeace.org/detox

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Box 4.3 Eleven flagship hazardous chemicals
1) Alkylphenols

4) Azo dyes

Commonly used alkylphenol compounds include
nonylphenols (NPs) and octylphenols and their ethoxylates,
particularly nonylphenol ethoxylates. NPs are widely used
in the textiles industry in cleaning and dyeing processes.
They are toxic to aquatic life, persist in the environment
and can accumulate in body tissue and biomagnify
(increase in concentration through the food chain).12 Their
similarity to natural oestrogen hormones can disrupt sexual
development in some organisms, most notably causing the
feminisation of fish.13,14

Azo dyes are one of the main types of dye used by the
textile industry. However, some azo dyes break down
during use and release chemicals known as aromatic
amines, some of which can cause cancer.23 The EU has
banned the use of these azo dyes that release cancercausing amines in any textiles that come into contact with
human skin.24

NPs are heavily regulated in Europe and since 2005 there
has been an EU-wide ban on major applications.15

2) Phthalates
Phthalates are a group of chemicals most commonly used
to soften PVC (the plastic polyvinyl chloride). In the textile
industry they are used in artificial leather, rubber and PVC
and in some dyes. There are substantial concerns about
the toxicity of phthalates such as DEHP (Bis(2-ethylhexyl)
phthalate), which is reprotoxic in mammals, as it can
interfere with development of the testes in early life.16
The phthalates DEHP and DBP (Dibutyl phthalate) are
classed as ‘toxic to reproduction’ in Europe17 and their
use restricted. Under EU REACH legislation the phthalates
DEHP, BBP (Benzyl butyl phthalate) and DBP are due to
be banned by 2015.18

3) Brominated and chlorinated flame
retardants
Many brominated flame retardants (BFRs) are persistent
and bioaccumulative chemicals that are now present
throughout the environment. Polybrominated diphenyl
ethers (PBDEs) are one of the most common groups of
BFRs and have been used to fireproof a wide variety of
materials, including textiles.
Some PBDEs are capable of interfering with the hormone
systems involved in growth and sexual development.19
Under EU law the use of some types of PBDE is tightly
restricted20 and one PBDE has been listed as a ‘priority
hazardous substance’ under European water law, which
requires that measures be taken to eliminate its pollution of
surface waters.21,22

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5) Organotin compounds
Organotin compounds are used in biocides and as
antifungal agents in a range of consumer products. Within
the textile industry they have been used in products such
as socks, shoes and sport clothes to prevent odour
caused by the breakdown of sweat.
One of the best-known organotin compounds is tributyltin
(TBT). One of its main uses was in antifouling paints
for ships, until evidence emerged that it persists in the
environment, builds up in the body and can affect immune
and reproductive systems.25 Its use as an antifouling paint
is now largely banned. TBT has also been used in textiles.
TBT is listed as a ‘priority hazardous substance’ under EU
regulations that require measures to be taken to eliminate
its pollution of surface waters in Europe.26 From July 2010
and January 2012 products (including consumer products)
containing more than 0.1% of certain types of organotin
compounds will be banned across the EU.27

6) Perfluorinated chemicals
Perfluorinated chemicals (PFCs) are manmade chemicals
widely used by industry for their non-stick and water-repellent
properties. In the textile industry they are used to make textile
and leather products both water and stain-proof.
Evidence shows that many PFCs persist in the
environment and can accumulate in body tissue and
biomagnify (increasing in levels) through the food chain.28,29
Once in the body some have been shown to affect the liver
as well as acting as hormone disruptors, altering levels of
growth and reproductive hormones.30,31
The best known of the PFCs is perfluorooctane sulphonate
(PFOS), a compound highly resistant to degradation;
it is expected to persist for very long periods in the
environment.32 PFOS is one of the ‘persistent organic
pollutants’ restricted under the Stockholm Convention, a
global treaty to protect human health and the environment,
and PFOS is also prohibited within Europe33 and in
Canada34 for certain uses.

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Section
four

7) Chlorobenzenes

10) Short-chain chlorinated paraffins

Chlorobenzenes are persistent and bioaccumulative
chemicals that have been used as solvents and
biocides, in the manufacture of dyes and as chemical
intermediaries. The effects of exposure depend on the type
of chlorobenzene; however, they commonly affect the liver,
thyroid and central nervous system. Hexachlorobenzene
(HCB), the most toxic and persistent chemical of this
group, is also a hormone disruptor.35

Short-chain chlorinated paraffins (SCCPs) are used
in the textile industry as flame retardants and finishing
agents for leather and textiles. They are highly toxic to
aquatic organisms, do not readily break down in the
environment and have a high potential to accumulate in
living organisms.42 Their use has been restricted in some
applications in the EU since 2004.43

Within the EU, pentachlorobenzene and HCB are
classified as ‘priority hazardous substances’ under
regulations that require measures to be taken to eliminate
their pollution of surface waters in Europe.36 They are also
listed as ‘persistent organic pollutants’ for global restriction
under the Stockholm Convention, and in line with this they
are prohibited or scheduled for reduction and eventual
elimination in Europe.37

8) Chlorinated solvents
Chlorinated solvents - such as trichloroethane (TCE) - are
used by textile manufacturers to dissolve other substances
during manufacturing and to clean fabrics.
TCE is an ozone-depleting substance that can persist
in the environment. It is also known to affect the central
nervous system, liver and kidneys.38 Since 2008 the EU
has severely restricted the use of TCE in both products
and fabric cleaning.39

11) Heavy metals: cadmium, lead, mercury
and chromium (VI)
Heavy metals such as cadmium, lead and mercury, have
been used in certain dyes and pigments used for textiles.
These metals can accumulate in the body over time and
are highly toxic, with irreversible effects including damage
to the nervous system (lead and mercury) or the kidneys
(cadmium). Cadmium is also known to cause cancer.44,45
Uses of chromium (VI) include certain textile processes
and leather tanning46: it is highly toxic even at low
concentrations, including to many aquatic organisms.47
Within the EU cadmium, mercury and lead have been
classified as ‘priority hazardous substances’ under
regulations that require measures to be taken to eliminate
their pollution of surface waters in Europe.48 Uses of
cadmium, mercury and lead have been severely restricted
in Europe for some time, including certain specific uses of
mercury and cadmium in textiles.49

9) Chlorophenols
Chlorophenols are a group of chemicals used as biocides
in a wide range of applications, from pesticides to wood
preservatives and textiles.
Pentachlorophenol (PCP) and its derivatives are used
as biocides in the textile industry. PCP is highly toxic to
humans and can affect many organs in the body. It is
also highly toxic to aquatic organisms.40 The EU banned
production of PCP-containing products in 1991 and now
also heavily restricts the sale and use of all goods that
contain the chemical.41

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image A Greenpeace
campaigner takes a
sample of wastewater
from a discharge pipe.

Contents
All companies mentioned in this report received a letter prior to
the report launching outlining the evidence found.
Where companies responded before the stated deadline with
responses deemed to be relevant, extracts from these responses
are included at the end of their respective brand profile.

Appendix 1
1) Main brands that have a business relationship
with Youngor Textile Complex
1.1 Adidas
1.2 Bauer Hockey
1.3 Cortefiel
1.4 H&M
1.5 Lacoste)
1.6 Phillips-Van Heusen Corporation (PVH Corp)
1.7 Nike
1.8 Puma
1.9 Youngor
(for Calvin Klein and Converse, see PVH Corp and Nike,
respectively)
2) Main brands that have a business relationship with
Well Dyeing Factory Limited
2.1 Abercrombie & Fitch
2.2 Meters/bonwe
2.3 Phillips-Van Heusen Corporation (PVH Corp)
2.4 Li Ning
3) The global market shares of sportwear companies

Appendix 2
Profiles of other brands linked with
Youngor Textile Complex

Appendix 3

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© GREENPEACE / QIU BO

Background information on the hazardous
chemicals found in the sampling

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Appendix 1
section 1

Appendix 1
1) Main brands that have a business relationship with Youngor Textile Complex

1.1 Adidas,
Herzogenaurach, Germany
“PERFORMANCE. PASSION. INTEGRITY. DIVERSITY.
These are the Adidas Group values. These are the core
values found in sport. Sport is the soul of the Adidas
Group. We measure ourselves by these values, and we
measure our business partners in the same way.”1
The Adidas Group is the world’s second largest sportinggoods company after Nike Inc, which is its only major
competitor; it plans to outgrow Nike in the sporting goods
industry in the next five years.
“Adidas’ mission is to be the leading sports brand in the world.”2

Adidas started out as a sport shoe factory, which is still
one of its main scopes. However, it has also expanded into
sports apparel, equipment and accessories, as well
as producing sport-inspired fashion.

Net sales concentrated on Europe (42%) and the Americas
(33%) in 2009, while Asia accounted for 25% of total sales.
Adidas has put a lot of effort into retail within the last five years.
At the end of 2009 the Adidas Group retail for the brands Adidas
and Reebok increased to 2,212 stores. The biggest Adidas
retail outlet – the ‘Adidas Brand Center’ – is located in Beijing.
“To minimise production costs” Adidas outsources 95%
of its production to independent third party suppliers,
primarily located in Asia.
“We strive to be a sustainable company, one that
recognises its responsibilities towards the environment,
our employees and the people who make our products.”3

“...At the end of the manufacturing process for
Adidas’ goods there is a washing process, but the
possibility that high concentrations of the chemicals
you mentioned can occur is very low...”
Adidas’ response to Dirty Laundry

Distribution of supplier production sites - Adidas

Europe & South Africa 6%

Americas 18%

46% China
Rest of Asia 30%

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81

Appendix 1 (continued)
1.2 Bauer Hockey,
Ontario, Canada

1.3 Cortefiel SA,
Madrid, Spain

“The business strategy of Bauer Performance Sports is
to continue to develop and bring to market high performing
products that improve the performance of athletes at
all levels.”5

“Cortefiel is the Group’s original brand. Created in 1946, it
targets men and women aged between 35 and 45.”10

4

Bauer Hockey was founded in Kitchener, Ontario in
1927. Bauer Hockey was owned for 12 years by Nike
Inc. from 1995 to 2008, when it sold Bauer Hockey to an
investor group led by Kohlberg & Company and Canadian
businessman W. Graeme Roustan for $200m in cash.6
In 2011, Bauer announced its intention to become a public
company, Bauer Performance Sports Ltd.7 Bauer makes
and markets equipment and clothing under the brands Bauer
Hockey, Mission Roller Hockey and Maverik Lacrosse.8
The company’s aims include: increasing its share of
the Ice and Roller Hockey market; targeting emerging
and underdeveloped consumer segments; growing
apparel across all sports categories, capitalising on the
rapidly growing lacrosse market and pursuing strategic
acquisitions.
The company does not refer to CSR, the environment or
sustainability; the only announcement on the website is
under the heading: Corporate Governance.
“Bauer Performance Sports Ltd.’s Board of Directors
considers good corporate governance to be an integral
part of the effective and efficient operation of the
company and essential to the enhancement of long-term
shareholder value. Bauer Performance Sports Ltd. is
committed to full and fair disclosure and providing timely,
accurate and complete compliance with the corporate
governance standards of Canadian securities regulators
and the Toronto Stock Exchange. Bauer Performance
Sports Ltd.’s governance system incorporates
transparency and high standards of ethics and discipline
that embrace best practices in corporate governance for
our shareholders.” 9

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The brand Cortefiel is one of four major brands of the
Cortefiel Group. It is present in 64 countries and has 1,729
points of sale.11 Grupo Cortefiel has generated retail sales
of €1.4bn in 2009.12 This translates into sales of roughly
€520m for the brand Cortefiel.
The Cortefiel Group has a Code of Conduct which applies
to suppliers and includes compliance with environmental
regulations.13 It has published a Sustainability Report that
gives details of its suppliers in China, Hong Kong and
Spain. 62% of all garment purchases are from Asia, while
only 36% of payments go to suppliers in Asian countries.14
Point 10 of the Code of Conduct states: “Respect for the
environment: It must be ensured compliance with the
environmental laws and regulations applicable in each
case, adopting a behaviour principle of a responsible and
respectful attitude towards the environment.

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Unravelling the corporate
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1.4 H&M Hennes
& Mauritz AB,
Stockholm, Sweden

Appendix 1
section 1

• Playing an active role in forming the Sustainable
Apparel Coalition, working to create a universal index
to show the environmental impact and fair labour
practices for clothing and footwear production.
• A global ban on sand-blasting for all its products.

H&M was established in Sweden in 1947, and today
sells clothing for women, men and children. It also sells
cosmetics, accessories and shoes. H&M employs 87,000
people, in over 2,200 concept stores in 40 countries, as
well as in 100 design centres, 16 production offices, and at
its headquarters in Stockholm, Sweden.
“Quality is a central issue, from the idea stage all the way
to the end customer. The quality work includes extensive
testing, as well as ensuring that the goods are produced
with the least possible environmental impact and under
good working conditions. H&M does not own any
production factories. Production of goods is outsourced
to independent suppliers, primarily in Asia and Europe,
through H&M’s local production offices.”15
H&M sources everything from around 700 independent
suppliers, primarily in Asia and Europe. Global sales
(turnover) in 2010 was €14bn16, probably making H&M the
world’s second largest speciality clothing retailer17.

• Saving 50 million litres of water in denim production
relative to previous production methods.

“We welcome your campaign as it deals with
an important topic, and we fully share your
ambitions and efforts to eliminate discharges of
hazardous chemicals. Any aim to put light on
the effects of industrial water pollution, wherever
it might appear, should be encouraged and is
something we all benefit from.”
“Ningbo Youngor Yinchen Uniform produces
blazers and trousers for H&M, but the very
fabric used for these garments comes from
fabric suppliers/textile mills outside of the
Youngor Garment city.”
H&M’s response to Dirty Laundry

H&M’s latest CSR report18 was published on 14 April
2011. H&Ms own highlights include:
• Announcing a target for all cotton to come from more
sustainable sources by 2020.
• A total of 68,000 cotton farmers were educated
on more sustainable farming practices through
engagement in the Better Cotton Initiative (BCI).
• Using more organic cotton than ever before in its
products, a total of 15,000 tonnes. This makes H&M
one of the largest users of organic cotton in the world
(2009: rank 5).
• Turning 1,600 tonnes of recycled materials into
new clothes.

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Appendix 1 (continued)
1.5 Lacoste,
Paris, France
Lacoste expresses itself through a large collection
of apparel for women, men and children, footwear,
fragrances, leather goods, eyewear, watches, belts, home
textiles, mobile phones and fashion jewellery.19 Lacoste SA
is owned 65% by the Lacoste family and 35% by Devanlay
(Maus family). Lacoste SA Devanlay is Lacoste’s worldwide
licensee.20
Lacoste is present in over 114 countries with the US, France,
UK, Italy and Spain being the most important markets.
An official CSR report was not found, however, the
Lacoste brand actively support “projects selected by the
Global Environment Facility to safeguard or protect certain
species of crocodiles, alligators, caiman or gavials now in
danger of extinction and whose the loss would jeopardise
the biological balance of their habitat areas.”21
“We have been committing ourselves to the
respect of the environment, notably through the
protection of biodiversity, and have asked our
worldwide licensees to act accordingly. We thus
consider very seriously the matter you have raised
and have immediately investigated it.”
Lacoste’s response to Dirty Laundry

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1.6 Phillips-Van Heusen
Corporation (PVH Corp),
New York, USA
PVH Corp is the world’s largest shirt and neckwear
company.22 PVH Corp provides products to many popular
US department stores and sells its products directly to
customers through about 700 outlet stores under the
brand names Van Heusen, IZOD, Bass and Calvin Klein.23
PVH Corp licenses its heritage brands globally for a range
of products through approximately 40 domestic and 50
international licence agreements covering approximately
150 territories.24
Its products are mainly casual apparel and sportswear.25
It has a range of private brands: Van Heusen, Calvin Klein,
Tommy Hilfiger, IZOD, ARROW, Bass, and GH Bass &
Co.26,27 Further brands include Chaps, DKNY, Donald J
Trump Signature Collection, Geoffrey Beene, IKE BEHAR,
J Garcia, JOE Joseph Abboud, Kenneth Cole New York,
Kenneth Cole Reaction, Michael Kors, Nautica, Sea John,
Ted Baker, Timberland and Jones New York.28
CSR seems to play an important (albeit relatively new) role
in PVH Corp’s self-image and outward communication:
“Central to our identity is a genuine commitment to
corporate responsibility, a fundamental component of how
we run our business that is directly linked to our strategies
and practices.”29 PVH Corp’s Environmental Statement
includes the following: “We recognise that our supply
chain processes impact the environment. While we do
not have direct control over our suppliers, vendors and
service providers, we […] seek to have our suppliers and
vendors meet our environmental requirements with respect
to wastewater treatment, hazardous chemicals, air quality
and recycling.”30

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Unravelling the corporate
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Appendix 1
section 1

1.7 Nike, Oregon, USA

In 2010, 35% of global sales were in North America, 20%
in Western Europe, 11% in emerging markets and 9% in
Greater China.

“There is no finish line for environmental efforts – we can
always go further”.31

Nike lists 612 contract factories in its 2009 Corporate
Responsibility report.32

Nike is the leading seller of athletic footwear and apparel in
the world; it sells its products through its own stores and
internet sales, and through a mix of independent distributors
and licensees, in over 170 countries around the world.

“Our commitment is to create extraordinary performance
products for athletes while managing our business within
nature’s limits.”

In the US, Nike owns 254 retail stores, 102 Cole Haan
stores, 35 Converse stores and 7 Hurley stores. Outside
the US, the company offers its products through 202 Nike
stores as well as 57 Cole Haan stores. The company also
offers its products across various countries through the
websites, Nike.com, nikestore.com and nikewomen.com.

“We are continuously working toward improving water
usage and management of water in our supply chain
and welcome Greenpeace’s stewardship in this area.
We hope this can be the beginning of a dialogue that
will lead to raising industry standards in this area.”
“Nike Inc currently sources from two factories in the
Youngor Group Co, Ningbo Youngor Knitting and
Underwear and Ningbo Youngor Sportswear in
Zhejiang Province.These factories are cut-and-sew
facilities. They do not have manufacturing processes
that include use of the chemicals called out in your
letter. In addition, neither factory sources materials from
the Youngor Dye House.”
Nike’s response to Dirty Laundry

Distribution of Nike contract factories globally

Japan 4%

28% Greater China

Emerging markets 53%
— including Asia
& C&S America

9% North America
2% Western Europe
4% C & E Europe

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Appendix 1 (continued)
1.8 Puma, Herzogenaurach,
Germany
“At Puma, we believe that our position as the creative
leader in Sportlifestyle gives us the opportunity and
the responsibility to contribute to a better world for the
generations to come.”
The Puma Vision is: Fair, Honest, Positive, Creative33
Puma designs and develops footwear, apparel and
accessories. Its Sport Fashion features collaborations with
renowned designer labels such as Alexander McQueen,
Mihara Yasuhiro and Sergio Rossi. It has a relatively
smaller share of the sportswear market in comparison with
Nike and Adidas.

Sourcing markets/Units
100%
75%
50%
25%
0%
Asia/Pacific

86

EMEA

America

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Puma distributes its products in more than 120 countries
and at the end of 2007 Puma had 116 Concept Stores.
This number is expected to be significantly higher now.
47% of its sales are in Europe and the Middle East (EMEA),
27% in the Americas and 22% in Asia/Pacific.
Puma has its own internal sourcing company by the name
of ‘World Cat’ and is therefore not reliant on external
sourcing agencies. The main focus of World Cat is on the
Asian sourcing market, with over 90% of suppliers located
in Asia.34 Puma does not publish an up-to-date list of
suppliers, although information from 2005 shows that 28%
of its suppliers were located in China at that point in time.
“The protection of the environment is extremely important
to PUMA. Our aim is not only to make the production of
our products transparent and environmentally friendly for
our partners and target groups, but also to continually
improve our standards.”
Sustainability Report 2007/8
“After having received your letter we immediately
contacted the supplier Youngor Knitting and can
confirm that Puma has a commercial relationship
with ready-made garment producer Youngor
Knitting, which is part of the Youngor Group, via
its national company Puma Japan...Youngor
Knitting annually produces 20,000 t-shirts, jackets
and pants for Puma Japan...However, the fabrics
mostly originate from Taiwan and Japan and from
producers which Puma nominated, therefore not
from the own-manufacturing of the Youngor Group
in Ningbo...The manufacturer working for Puma
Japan only has facilities for cutting and tailoring.”
Puma’s response to Dirty Laundry

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1.9 Youngor, Ningbo, near
Shanghai, China
“Youngor’s commitment to social responsibility began
early, and announced a policy of ‘honesty, pragmatism,
responsibility, and harmony’ and began making altruism a
top priority for the group.”35
Youngor is China’s largest integrated textile company,
with world-scale fabric manufacturing, garment making
and retailing capabilities. It is based in Ningbo city, near
Shanghai, in China’s eastern Zhejiang province, and was
established in 1979. Li Rucheng, the CEO, developed
the small garment manufacturing company into an
international garment and textile giant.

Appendix 1
section 1

Youngor Knitting’s website states that it “…is now supplying
Lacoste, Abercrombie&Fitch, Polo Ralph Lauren, Adidas,
Youngor, Perry Ellis, Calvin Klein and other world-renowned
clients with 8,000 tons of knitted fabrics and 1.2 million
dozens of T-shirts, casualwear items, and sportswear
items.”39 Further famous brands with links to Youngor
subsidiaries are Nike, Puma and Hummel.40
In 2008, Youngor acquired Smart Shirts Limited, the former
menswear division of Kellwood, one of the top five companies
in the US clothing industry, and the Xin Ma Group, one of the
top three garment manufacturers in Hong Kong.41
Currently, Youngor has more than 100 branches, 400
exclusive shops and 2,000 retail outlets in China.42 In
2001, Youngor opened its giant flagship store, the largest
of its kind in China, in Shanghai’s Nanjing Road – China’s
first commercial street.43 Through Smart Shirts it has
access to outlets in hundreds of US department stores.44

Youngor is the world’s largest menswear manufacturer,
with a production capacity of 80 million clothing items a
“Youngor Sunrise Textile and Garment Company is
year. In 2009 it was ranked first by the National Garment
Association as the company with the highest sales revenue presently applying for the ‘Clean Production Company’
licence from China’s National Cleaner Production Centre.
and sales profit.36
The company is taking this opportunity to further promote
Youngor’s product line includes shirts, suits, trousers,
cleaner production and the use of green energy.”45
casual jackets, ties and T-shirts, all officially recognised as
leading national brands. In future, Youngor aims to promote
its brand image with three branch styles: casual-fashion
“We take the problem which Greenpeace raised
wear (GY - Green Youngor); business wear (Youngor CEO);
seriously and we will work with Greenpeace to
and officials’ wear (MAYOR & YOUNGOR).37
find a solution.”
31% of sales revenues are generated on the domestic
Chinese market, with 69% coming from international
markets, mainly the US, Europe and Japan.38

Youngor’s response to Dirty Laundry

The company is not only a brand it is also a supplier.
Youngor has established 156 subsidiaries nationwide to
offer pre-sales, sales, and post-sales customer service.

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87

Appendix 1 (continued)
2) Main brands that have a business relationship with Well Dyeing Factory Ltd.

2.1. Abercrombie & Fitch,
Ohio USA

2.2 Meters/bonwe,
Shanghai, China

The A&F brand profiles itself as an international, classical,
near-luxury, and youthful All-American lifestyle brand.46,47
Its specialties are premium-priced goods rather than
necessities.48,49

The company initiated an “outsourced production and
combined retail of company-owned and franchisee sales”
business model in China, through sourcing from over
300 suppliers concentrated in the Yangtze River Delta
and Pearl River Delta, and setting up 300 franchisees and
company-owned stores throughout mainland China.54

Abercrombie & Fitch sells its own brand of clothing and
accessories to a customer base that is primarily under 30
years old. It sells the vast majority of its wares in American
malls through its four different store brands (Abercrombie
& Fitch, abercrombie, Hollister, and Gilly Hicks), each of
which caters to different age groups.50
Abercrombie & Fitch operated 38 international stores at the
end of 2009 and plans to open 29 new international stores
in 2010. These include 25 mall-based Hollister stores,
its first Gilly Hicks store in the UK, and flagship stores in
Denmark and Japan. Accelerated international expansion
is part of ANF’s growth strategy with international sales
increased 102% in Q1 2010.51 Abercrombie & Fitch
opened its first Asian flagship in Japan in December
2009.52,53
There is no CSR report publicly available.

“Abercrombie & Fitch is a member of the Apparel Mills
and Sundries Program through Business for Social
Responsibility (BSR) ... The onus on this issue is shared
with the Well Dyeing Factory to accept the initiative and
become a participant in the BSR program.”
Abercrombie & Fitch’s response to Dirty Laundry

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There are now about 3,000 franchised stores within China
and total sales of ¥7bn in 2008, ranking first among all the
local and international casual wear brands in the domestic
market.55
“The company sees environmental protection as an
important part of its sustainable development strategy and
aims to guide its environmental protection and sustainable
development strategy with reference to international
standards.”56

2.3 Philips van Heusen
Corporation (PVH Corp),
New York, USA
(see 1.6 above)

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2.4 Li Ning, Beijing, China
“A world-leading brand in the sporting goods industry.”57

Appendix 1
section 2

an abundant supply of contract manufacturers in the PRC
and we will continue to focus on product development and
brand management, we have no intention to expand our
manufacturing operations in the foreseeable future.”

In 2009, Li Ning published its first CSR report, which was
also the first in the Chinese sporting goods industry.62
The report “...sets out the requirements for suppliers in
Li Ning is engaged in brand marketing, research and
performing their social responsibilities in respect of labour,
development, design, manufacturing, distribution and retail safety and environmental protection, which are used by
of footwear, apparel, accessories and equipment for sport the Group as one of the criteria in identifying new suppliers
and leisure under its own Li-Ning brand and five others, in
and assessing the existing suppliers. Enterprises are a
a multi-brand business development strategy, mainly in the part of the community and both the natural and the social
Peoples Republic of China (PRC).
environment are indispensable to enterprises. While
creating commercial value, the Group keeps a close eye
Li Ning’s popularity and success to date is mainly based
on the harmonious coexistence of itself with the nature and
on the domestic market; the Group calls itself one of the
the society in pursuit of sustainable development.”
leading sportswear brands in China.58 In 2010 there were
7,478 Li Ning brand retail stores in China (made up of 7,004
brand franchises and 474 directly-managed retail stores in
18 provinces and municipalities).59 Li Ning has more than 30
“We take the problem Greenpeace raised seriously.
subsidiaries in China, one in the US, one in Germany and one
Well Dyeing is our fibre supplier. We have confirmed
in Spain.60
that Well Dyeing has received Greenpeace’s
Li Ning Company Limited was founded by the Olympic gold
medal-winning gymnast Li Ning in Beijing, China in 1989.

The manufacturing of Li Ning products is undertaken by
Guangdong Li Ning Sports Development Company Ltd
other independent third party manufacturers.61
“We will continue to engage contract manufacturers in the
production of our products and contract manufacturers will
remain as our major suppliers in the near future. As there is

letter. We have asked them to investigate their
pollutant discharge immediately and report back
to us. We asked Well Dyeing to proactively contact
Greenpeace and cooperate with you.”
Li Ning’s response to Dirty Laundry

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89

Appendix 1 (continued)
3. The global market shares of
sportswear companies
In general, the textile and clothing industry is highly
fragmented, including a wide range of brands. In the
US, the 50 largest brands generated less than 40%
of revenue63, and in the EU, more than 60 companies
generated about 25% of revenue64. The sportswear
industry is less fragmented with a few large companies, in
particular Nike and Adidas, having a high level of influence.
The following charts show the market shares of sportswear
companies.
Athletic Apparel - Global Market Shares65
7%
6%
2%
2%
3%
2%
76%

2%

Nike
Adidas
Reebok
Quicksilver
VF Knitwear
Columbia
Puma
Others

Athletic Footwear - Global Market Shares66
Nike

18%

5%
2%

Adidas
image A Greenpeace
campaigner takes a
sample of wastewater
from a discharge pipe.

Reebok
Puma
New Blaance

4%

ASICS

5%

Converse

6%
7%

90

31%

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

K-Swiss

16%
6%

Sketchers
Others

Greenpeace
International

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Unravelling the corporate
connections to toxic water
pollution in China

© GREENPEACE / QIU BO

image Textile
factory at the
Pearl River Delta.

Appendix 1
section 3

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91

Appendix 2
Profiles of other brands linked
with Youngor Textile Complex
Blažek Praha, Czech Republic

Nautica was bought by VF Corporation in 2003.11
VF Corporation, a leader in branded quality apparel also
owns brands like Lee, Wrangler, Reef, Vans and Eastpak.12
Base mainly in the US, there are about 200 Nautica brand
stores operated by independent licensees throughout
the world, with the majority located in southeast Europe,
Central America and China.13

Blažek Praha was established in 1992. Today it is first
among apparel manufacturers in the Czech market. Its main
The VF Corporation has Global Compliance Principles
activity is the manufacture and sale of men’s clothing.1
that include the environment: “Facilities should have policies
“Apart from suits, shirts, ties, coats and cloaks, Blažek offers
and procedures in place to ensure environmental impacts are
jackets, pullovers, t-shirts, jeans, underwear and accessories,
including a whole collection of shoes and bags as well.”2

Revenues from production in 2010 were 400m Czech
koruna (€16m), and from retail sales in 2010 350m koruna
(€14m). Blažek employs 98 people.3

minimised with respect to energy, air emissions, water, waste,
hazardous materials and other significant environmental risks.
Facilities are expected to make sustainable improvements
in environmental performance and require the same of their
suppliers and sub-contractors.”14

Blažek does not refer to environmental issues on its
Oxford Apparel Group, Atlanta,
website, but focuses mainly on social topics, such as equal
Georgia, USA
opportunities, fair play and human potential.4
Macy’s, Cincinnati Ohio, USA
Macy’s Inc has corporate offices in Cincinnati and
New York and is one of the US’ premier retailers, with
fiscal 2010 sales of $25 billion.5 Macy’s Inc employs
approximately 166,000 people6 and is recognised
as a retail industry leader in developing private brand
merchandise.7

Oxford
Apparel

Oxford Apparel produces branded and private label
dress shirts, suited separates, sport shirts, casual slacks,
outerwear, sweaters, jeans, swimwear, western wear and
golf apparel. It also sells products under the Oxford Golf
and various Ely & Walker trademarks, and the Hathaway
trademark.15

Oxford Apparel used to be part of Oxford Industries;
in January 2011 it was sold to Li & Fung USA; Oxford
Apparel generates about $220m a year.16 Oxford Apparel
CSR is important for Macy’s self-image and outward
products are sold to a variety of department stores,
communication; “At Macy’s, Inc. we believe that contributing
mass merchants, speciality catalogue retailers, discount
to a more sustainable environment is good business practice
retailers, speciality retailers, ‘green grass’ golf merchants
and the right thing to do for future generations. As a leading
and Internet retailers throughout the US.
national retailer with a significant workforce, we have the
opportunity to make a meaningful difference in improving the
environment. And we will do so by using resources
more efficiently, providing eco-friendly products that meet
customer expectations and striving to reduce our overall
impact on the environment.”8

Nautica, New York USA
Founded in 1983, Nautica has evolved from a collection
of men’s outerwear to a leading global lifestyle brand, with
products ranging from men’s, women’s and children’s
apparel and accessories to a complete home collection.9
“Products including Nautica Golf, fragrances, neckware,
footwear, watches, hosiery, eyewear, rainwear, leather belts,
wallets, gloves, scarves, and home furnishings are also
licensed across the globe in over 20 countries.”10

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Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Li & Fung Limited, the parent company of LF USA, has a
large section on corporate responsibility on its website,
but little information regarding the environment, of which
most is climate-change related. The only statement related
to suppliers or subsidiaries is: “We regularly report on our
progress on various environmental measures through the
annual reports of our subsidiary companies and, at the group
level, through various means such as the UN Global Compact
Communication on Progress Report.”17

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Appendix 2

Peerless Clothing Inc, Montreal,
Quebec, Canada & New York, USA

Profiles of other brands linked
with Well Dyeing Complex

“Largest manufacturer of men’s clothing in North America.”18

American Eagle,
Pittsburg, PA, USA

The company does not advertise itself and generally keeps
a very low profile. It produces licensed clothes for a large
variety of brands. These include designer labels such as
Lauren Ralph Lauren, Calvin Klein, DKNY, Tallia Orange,
Sean John, Michael Kors, Joseph Abboud, Elie Tahari,
Izod, Van Heusen, Bill Blas and Hickey.19
“Founded in 1919, Peerless Clothing, Inc. is the largest
domestic producer of men’s tailored clothing in North America
... The company supplies men’s tailored clothing to most
every major department and specialty store retailer in the
United States.” 20
“Peerless Clothing has doubled its revenue in the past
few years…”21

“Upon review of your letter to Peerless Clothing
Inc, I would like to inform you that we no longer use
Youngor Group.”
Peerless’ response to Dirty Laundry

Polo Ralph Lauren,
New York, USA
“Our Company is a global leader in the design, marketing and
distribution of premium lifestyle products including men’s,
women’s and children’s apparel, accessories, fragrances and
home furnishings.” 22
“Our brand names include Polo by Ralph Lauren, Ralph
Lauren Purple Label, Ralph Lauren Women’s Collection, Black
Label, Blue Label, Lauren by Ralph Lauren, RRL, RLX, Rugby,
Ralph Lauren Childrenswear, American Living, Chaps and
Club Monaco, among others.”23

Ralph Lauren contracts to over 400 different
manufacturers worldwide. In fiscal 2010, over 98% of
Ralph Lauren products (by dollar volume) were produced
outside the US, primarily in Asia, Europe and South
America.24 “None of the manufacturers we use produce our
products exclusively.”25

No CSR or statements on the environment from Polo
Ralph Lauren could be found.

American Eagle (AEO) is a mall-based apparel and
accessories retailer that sells its own brands and products
throughout the US and Canada. AEO operates three
different chains, each of which targets a different segment
of customers within the broad 15-40 age group.26 The
overwhelming majority of AEO’s sales come from its
namesake American Eagle operations.27
The first three outlets in China, scheduled to open in
early 2011, are earmarked for Hong Kong, Beijing
and Shanghai.28,29
AEO has a CSR programme that includes four key focus
areas: Supply Chain Factories, Environment, Employees
and Communities. “Our environmental strategy is built on
four pillars: conserve resources, minimise waste, improve
product and packaging, and enhance engagement. We still
have a long way to go in developing our comprehensive
sustainability programme, but step by step, we are beginning
to reduce our environmental footprint.” 30

“We are familiar with Well Dyeing and understand that
it has supplied fabric for our garments in the past. We
have confirmed that Well Dyeing does not have any
fabric programmes currently in development for our
garments at this time.”
American Eagles’ response to Dirty Laundry
Carters (CRI), Atlanta,
Georgia, USA
Carter’s produces casual apparel, accessories, bedding,
room décor, toys for babies, toddlers and kids. Carter’s is
the leading brand of children’s clothing in the US today.31
Carter’s CSR programme focuses almost exclusively
on children’s charity. It makes the following reference
to the environment in its Annual Report 2010: “We are
subject to various federal, state, and local laws that govern
activities or operations that may have adverse environmental
effects. Noncompliance with these laws and regulations can
result in significant liabilities, penalties, and costs. Generally,
compliance with environmental laws has not had a material
impact on our operations, but there can be no assurance
that future compliance with such laws will not have a material
adverse effect on our operations.”32
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93

Appendix 2 (continued)
GAP, San Francisco, California, USA

JC Penney, Texas, USA

Gap Inc is one of the world’s largest speciality retailers,
with more than 3,000 stores. In the long term, Gap plans
on expanding their international operations from their
current base of 332 stores (as of May 2010) in Europe and
Asia. Its international operations are split between the Gap
and Banana Republic - Old Navy does not have stores
outside of North America.33 Gap currently has franchise
agreements in place for 24 countries on four continents;
130 franchise stores are open in Asia, Europe, Latin
America and the Middle East. In 2010 Gap plans to open
stores its first stores in Australia and China.34 Apart from
improving international and online sales, the company is
also looking to revive its flagging sales and market share in
North America.35

JC Penney (JCP) produces its own private brands in
addition to selling products from other companies, with a
high reliance on private-label goods. Brands include Call
It Spring, Bisou Bisou, Arizona, I (love) Ronson, Decree,
Cindy Crawford Collection, J Ferrar, JOE, Linden Street,
a.n.a. American Living, Mango, Modern Bride, Nicole, Okie
Dokie, Ambrielle, Alan B Worthington, Olsenboye, One
Kiss, Sephora, Stafford, St John’s Bay, Studio, Supergirl,
cooks and Liz Claiborne.39

The CSR report is very comprehensive and centres around
the mantra “Embracing our responsibility”.36
“Around the world, we’re reducing waste, saving energy, and
incorporating sustainable design into everything from our
products to our stores.”37
“Clean Water Program: We’re requiring special treatment of
water used to launder Gap, Banana Republic, and Old Navy
denim to ensure that it’s clean and safe when it leaves the
denim laundry.”38

“We work hard to ensure our business is handled in a
socially and environmentally responsible manner, and
we take claims such as these very seriously.”
Gap’s response to Dirty Laundry

JC Penney’s has 1,108 department stores.
JCP has “Matters of Principle” in environmental responsibility
that commit the company to “…. continually review its
operations for the purpose of assessing their potential impact
on the environment or on related human health or safety
issues; and develop and implement plans, programmes,
and policies for eliminating or minimising significant threats
to the environment or to human health or safety that may be
identified. (...)” 40

Kohls, Wisconsin, USA
Kohl’s (KSS) is a US department store chain that sells
a mix of items including men’s and women’s apparel,
home decor, and accessories. The department store
appeals to middle-class consumers by selling discounted
branded and private label clothing and home goods. It
competes with other US national department stores such
as JC Penney and Macy’s Inc.41 As of year-end 2010, it
operated 1,089 stores and also offers online shopping. It
has no stores outside of the US.42
Kohl’s has a website on Advancing Environmental
Solutions43 as well as a CSR report (2010), where it is
stated: “Kohl’s Environmental Mission: Kohl’s is committed
to protecting and conserving the environment by innovative
solutions that encourage long-term sustainability.” 44

94

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Semir, Wenzhou City, China
The Semir Brand, established in 1996, has become a
leading brand in China’s casual clothing industry. The
brand now has over 3,000 outlets across China. Its clothes
are designed with a focus on vitality and fashion and are
targeted at a younger audience.
Semir follows the environmental policy of “strictly following
laws, preventing pollution, conserving resources, and
continuous improvement.” The company proactively
develops high-quality strategic suppliers and strictly
controls production according to quality assurance system
procedures.45

Appendix 2

Yishion, Humen DongGuan City,
China
Yishion sells casual wear and sports wear. It has 19
regional offices in China and over 3,000 franchised stores.
Since 2003, operations have been expanded to Bahrain,
Hong Kong, Iran, Jordan, Kuwait, Malaysia, Oman, Qatar,
Saudi Arabia, United Arab Emirates and Vietnam.51
Yishion supported the anti-drugs campaign in China
and educational programmes to help people in need.
However, there is no information publicly available about
the environment or sustainability.

A Semir advertisement saying “I can’t stop global
warming, but at least I look good” received criticism
from many environmentalists and net citizens.46
Uniqlo, Yamaguchi, Japan
Fast Retailing is the holding company for Uniqlo, which is
a retail chain operator specialising in in-house designed
casual clothing for men and women of all ages. It operates
829 stores under the name of UNIQLO, mostly in Japan
but with international outlets, as well as having an online
store. With worldwide sales of €7.31bn in 2009, Uniqlo
ranks fourth among worldwide apparel speciality stores
(not including department stores).47 About 75% of its sales
are from Japan.48
Fast Retailing’s CSR Report 2011 has statements
regarding production and its supply chain: “Fast Retailing
complies with environmental laws and keeps abreast of
issues facing the international community and the global
environment. We believe the first thing Fast Retailing can do to
minimise its environmental impact is to improve management
efficiency.”49

With regard to its business and major environmental Impacts,
it lists among other things: “Carrying out environmental
initiatives at factories. We introduced the FR Environmental
Standards at material factories and commenced
monitoring.“50

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95

Appendix 3
Background information on the hazardous chemicals found in the sampling

Organic Chemicals

This section provides further information on
some of the organic chemicals found in the
samples of effluent collected from Youngor
Textile Complex (Pipe 1) and Well Dyeing
Complex (Pipe 1) and on the heavy metals
found at high concentrations in the effluent
collected from Well Dyeing Complex (Pipe
1). For details of all of the chemicals found
and the effects of key substances see the full
technical report by the Greenpeace Research
Laboratories.1

The presence of this diverse array of chemicals at
concentrations in the low or sub parts per billion range
indicates that the effluent discharged from these two
facilities is acting as a point source (in some cases a
periodic point source) of a range of hazardous substances
to the local aquatic environment. On the basis of
information available, it is not possible to determine
the specific sources of these various substances in the
wastewater within the facilities, though they could include
the deliberate use of these chemicals in processing and
finishing operations on the site or the washing out of
residues of such chemicals or their degradation products
from yarn, fabric or textile products brought on to the site
for processing from manufacturers located elsewhere.
Further detailed investigations of activities taking place
within the facility would be necessary in order to determine
likely sources.

What are these organic chemicals?
Organic chemicals
isolated in samples

Manufacturing facility and
sample reference where found

Where and how they are used, particularly Known effects on the environment and
in the textile industry
human health

Alkylphenols
(nonylphenol and
octylphenol)

Youngor Textile Complex; 14µg/l
nonylphenol in the effluent
collected from Pipe 1 at 1100 on
8th March 2011 (CN11001)

These chemicals are formed by the
breakdown of nonyl phenol ethoxylates
(NPEs) and octyl phenol ethoxylates (OPEs)
respectively, substances which are used as
detergents,,surfacants and dispersants (eg.
during dyeing)
in numerous industrial processes, including
during the manufacture of textiles. Nonyl and
octyl phenols do also have other industrial
uses in their own right.

Nonyl phenols (NPs) and octyl phenols
(OPs) are well known persistent and
bioaccumulative

The unique properties of perflourinated
chemicals (PFCs) have led to their widespread
use as water-, grease- and stain-repellent
finishes for textiles and papers; specialised
industrial solvents and surfactants; ingredients
in cosmetics, plastics2,3, firefighting foams;
and ingredients in lubricants for hightemperature applications.4

PFCs are man-made chemicals which are
not produced by natural processes and
hence never occur in nature other than as
a result of human activity. They are highly
resistant to chemical, biological and thermal
degradation5, and many are also relatively
insoluble in both water and oils. PFCs
bioaccumulate, including in humans and
have a range of impacts on the environment
and human health, for example they
impact the developing immune system,
and have adverse effects on the liver in
mammals.6,7,8,9,10,11 Some have also been
shown to act as hormone disruptors.12
See Box 2.1.

Well Dyeing (CN10013, effluent,
Pipe 1), nonylphenol and
octylphenol.
Perfluorinated
chemicals

96

Youngor Textile Complex; in all
3 samples collected March 2011
(CN11001, CN11002, CN11003)
perfluoroctanoic acid (PFOA) was
found at concentrations between
0.13 and 0.14 µg/l (130-140
ng/l). Other perfluorocarboxylic
acids were also found, though
at concentrations around an
order of magnitude lower (0.0130.031 µg/l, 13-31 ng/l), while
perfluoroctane sulphonate (PFOS)
was present at lower levels again
(0.0031-0.0087 µg/l, 3.1-8.7 ng/l).

See Box 2.1.

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

environmental contaminants, with
hormone-disrupting properties for many
aquatic organisms. More information on
these substances is presented in Box 2.2.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Appendix 3

Organic chemicals
isolated in samples

Manufacturing facility and
sample reference where found

Where and how they are used, particularly Known effects on the environment and
in the textile industry
human health

Trialkyl phosphates,
including
tributylphosphate
(TBP),
triethylphosphate
(TEP) and tris
(2-ethylhexyl)
phosphate (TEHP)

Youngor Textile Complex TBP
was found in effluent from Pipe 1
(sample CN10042. TEHP was
found in effluent samples CN11001,
CN11002 & CN11003.

Tributyl phosphate (TBP) is widely used in
various industrial processes, including by
the textile industry due to its properties as a
strong wetting agent and strong polar solvent.

TBP is continuously lost to the air and
water during use; it degrades slowly or
moderately in the environment. TBP is toxic
to aquatic life, for example some protozoa
species, and can have acute toxicity to fish.

Quinone and
di-ketone
derviaties; eg. the
anthraquinone (AQ)
derivative aminoanthraquinone and
the benzophenon
derivative methyl
2-benzoylbenzoate

Youngor Textile Complex aminoanthraquinone in effluent from
Pipe 1 (samples CN10042 &
CN10050,)

Synthetic AQs are widely used in dyeing
operations (second in bulk only to azo dyes13,
most commonly for cotton, cellulose-based
fibres and some synthetic fabrics14. The AQ
derivative identified (amino-anthraquinone) is
a common intermediate in the synthesis of a
range of AQ dyes, many of which can degrade
to release amino-anthraquinone.15

Many AQ derivatives are known to be
toxic to animals and/or plants (see e.g.
Sendelbach 198916 for a review of early
evidence); indeed, their ability to cause
oxidative damage to DNA in dividing cells
has led to their use in very controlled doses
as anti-tumour drugs, among other medical
applications.17 Amino-anthraquinone
has been shown to be carcinogenic in
laboratory studies, as well as damaging
to the kidneys. Its degradation products
are toxic to aquatic life as well as being
persistent. More information on AQ and
its derivatives and the toxicity of methyl
2-bezoylbenzoate is given in Box D in the
Technical Note.18

Amines from the
breakdown of Azo
dyes, including
aniline, chlorinated
anilines such as
dichloroaniline (DCA
or 2-chloroaniline),
methylaniline,
ethylaniline and
diethylaniline as
well as o-anisidine

Youngor Textile Complex; in all 3
effluent samples collected March
2011 (CN11001, CN11002,
CN11003), aniline, 2-chloroaniline,
methylaniline, ethylaniline and
diethylaniline were found (at
concentrations ranging from
0.1-2.1 µg/l)k, as well as the
carcinogenic form o-anisidine (at
0.07-0.08 µg/l).

Well Dyeing: TBP and TEP were
found in effluent from Pipe 1
(sample CN10013,

Well Dyeing; the benzophenone
derivative methyl
2-bezoylbenzoate in effluent from
Pipe 1 (Sample CN10013).

The benzophenone derivative, methyl
2-benzoylbenzoate, has uses as a
photoinitiator in UV-curable inks.

Anilines are an important class of
environmental water pollutants due to
their wide usage and high solubility in
water. The release of anilines into the
environment within industrial effluents has
been previously reported, including within
effluents from the textile sector.21,22 Aniline
and its chlorinated derivatives, including
mono-, di- and trichlorinated isomers,
are toxic to a wide range of aquatic
organisms.23

Chlorophenols are a group of chemicals used
as biocides in a wide range of applications,
from pesticides to wood preservatives and
textiles. The EU banned production of PCPcontaining products in 1991 and now also
heavily restricts the sale and use of all goods
that contain the chemical.24

PCP is highly toxic to humans and can
affect many organs in the body. It is also
highly toxic to aquatic organisms.25

Chlorinated solvents, such as trichloroethane
(TCE), are used by textile manufacturers
to dissolve other substances during
manufacturing and to clean fabrics. Since
2008 the EU has severely restricted the use of
TCE in both products and fabric cleaning.26

Chlorinated solvents are volatile
compounds, some of which are persistent
and resist biodegradation.. For example,
TCE is an ozone-depleting substance that
can persist in the environment. It is also
known to affect the central nervous system,
liver and kidneys.27,28

Well Dyeing (CN10013, Pipe 1)
dichloroaniline (DCA)

Youngor Textile Complex: di-, triChlorophenols
and pentachlorophenols in effluent
- di-, tri- and
pentachlorophenols from samples CN11001, CN11002
& CN11003) in the range of 0.030.06 µg/l

Chorinated solvents
(dichloroethane,
trichloromethane &
tetrachloroethene)
were present at low
concentrations.

Azo dyes are one of the main types of dye
used by the textile industry. However, some
azo dyes break down during use and release
chemicals known as aromatic amines, some
of which can cause cancer.19 The EU has
restricted the use of azo dyes that release
cancer-causing amines in any textiles that
come into contact with human skin.20

Youngor Textile Complex:
dichloroethane (0.9 µg/l in
CN11003), trichloromethane/
chloroform (all three
samples at 0.9-4.8 µg/l) and
tetrachloroethene (0.4 µg/l in
CN11002 and CN11003),

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97

Heavy Metals
In addition to the organic chemicals identified, the
wastewater sample from Well Dyeing Complex pipe 1
(CN10013) also contained concentrations of dissolved
chromium (42 μg/l), copper (24 μg/l) and nickel (37 μg/l) at
levels that were slightly elevated (2-4 times higher) above
levels typically found in uncontaminated surface waters.
Background surface waters concentrations of dissolved
chromium and copper are both typically below 10 μg/l,
and often far lower, while those of nickel are generally
below 20 μg/l.29,30,31,32 The levels of dissolved chromium,

Far higher total concentrations (dissolved forms plus
those bound to suspended particulates) were found for
most metals in the whole (unfiltered) sample from pipe 1
(CN10013) – total chromium (2820 μg/l), copper (13400 μg/l)
and nickel (2800 μg/l). These metals were present almost
exclusively (99% or more) in particulate-bound forms.
image: A Greenpeace
campaigner takes a
sample from
a wastewater
discharge pipe.

© GREENPEACE / QIU BO

98

copper and nickel in these samples were considerably
lower than their maximum allowable concentrations under
the Guangdong effluent standard33 and effluent standards
specific to the textile industry.34

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

Greenpeace
International

Dirty Laundry
Corporate connections to
hazardous chemical water
pollution by the textile
industry in China

Appendix 3

Metals
Chromium (Cr) is primarily used in the metallurgical
industry (in stainless steel and other alloys), as well as
in various industrial processes including leather tanning
and certain textile processes.35,36 Hexavalent chromium
compounds are used in metal finishing (chrome plating),
and also in certain textile manufacturing processes, in wood
preservatives and as corrosion inhibitors.37,38 Chromium
normally exists in the environment in trivalent Cr(III) forms
which generally have very low solubility in water and tend
to rapidly precipitate or adsorb onto suspended particles
and bottom sediments; hexavalent Cr(VI) forms can exist,
though far less frequently, and these compounds are usually
converted rapidly to trivalent Cr(III) compounds by reducing
compounds. Hexavalent forms tend to be readily soluble
in water and therefore can be highly mobile in aquatic
environments.39,40,41 Uncontaminated surface water typically
contains less than 10 μg/l of chromium, and concentrations
in uncontaminated freshwater sediments are typically below
100 mg/kg.42,43 Chromium (III) is an essential nutrient for
animals and plants, though large doses may be harmful. In
contrast, hexavalent chromium is highly toxic even at low
concentrations, including for many aquatic organisms.44
Hexavalent chromium compounds are also corrosive, and
in humans allergic skin reactions readily occur following
exposure, independent of dose.45 Furthermore, hexavalent
chromium is a known human carcinogen under some
circumstances.46 The Chinese national wastewater
discharge standard and the equivalent Guangdong
Province standard set the same maximum permissible
concentrations of 1500 μg/l (1.5 mg/L) total chromium, and
of 500 μg/l (0.5 mg/L) hexavalent chromium.47.48
Copper (Cu) is a widely used metal, primarily as a pure
metal or as part of mixtures (alloys) with other metals,
though there are also many other uses of copper
compounds, including within metal finishing processes
and textile manufacturing, including dyeing processes.49
The manufacture of plumbing materials is one of the main
uses of main uses of copper metal and alloys, in part due
to the malleability and thermal conductivity of copper.50
Levels of copper in the environment are typically quite
low, commonly less than 50 mg/kg in uncontaminated
freshwater sediments.51 Background concentration of
dissolved copper in uncontaminated surface waters
can vary significantly, but levels are typically below 10

μg/l, and often far lower.52,53 Copper is an important
element for humans and animals in low doses. However,
exposure to high levels of bioavailable copper can lead to
bioaccumulation and toxic effects.54 Releases of copper to
aquatic systems are of particular concern as many aquatic
organisms are extremely sensitive to copper, particularly in
soluble forms which are generally far more bioavailable and
toxic to a wide range of aquatic plants and animals55,56 with
some effects occurring even at very low concentrations57.
The Chinese national wastewater discharge standard
and the equivalent Guangdong Province standard set the
same maximum permissible concentrations of copper of
between 500 and 2000 μg/l (0.5 - 2.0 mg/L) depending on
how the receiving water body is used.58,59,60
Nickel as a metal and its alloys, as well as nickel
compounds, has many industrial uses, including
in metal plating, the manufacture of plumbing and
electronic devices, in catalysts, batteries, pigments and
ceramics.61,62 Nickel is also used in certain textile dyes (eg
phthalocyanine dyes), but to a lesser extent than other
metals such as copper and chromium.63
Levels of nickel in the environment are typically low,
with uncontaminated freshwater sediments generally
containing below 60 mg/kg nickel and concentrations in
uncontaminated surface waters typically below 20 μg/l.64,65,66
Although nickel bound to sediments and soils is generally
persistent, water-soluble nickel compounds can be quite
mobile. Very small amounts of nickel are essential for normal
growth and reproduction in most animals and plants, and
this is most likely also true for humans.67 However, toxic
and carcinogenic effects can result from exposure to higher
concentrations for a wide range of life forms, including
gastrointestinal and cardiac effects.68,69 In humans, a
significant proportion of the population (2-5%) are also nickel
sensitive, and effects can occur in sensitised individuals at far
lower concentrations.70 For some aquatic organisms, impacts
can occur at very low nickel concentrations.71 Furthermore,
some nickel compounds have been classified as carcinogenic
to humans, and there is also evidence of carcinogenicity in
animals.72,73 The Chinese national wastewater discharge
standard and the equivalent Guangdong Province standard
set the same maximum permissible concentrations of nickel
of 1000 μg/l (1.0 mg/L) .74,75

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99

image: At 5am in the
morning, large quantities of
polluted water pour out from
the discharge pipe of the
Youngor textiles factory, in
Yinzhou district, Ningbo. The
discharge pipe flows directly
into the Fenghua River.

100

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Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

Appendix 3

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

© GREENPEACE / QIU BO

Greenpeace
International

101

References
Executive Summary
1 Measured as chemical oxygen demand. The “Chemical Oxygen
Demand (COD) test is commonly used to indirectly measure
the quantity of organic compounds in wastewater or surface
water (e.g. lakes and rivers), making COD a useful measure of water quality.
2 For all information: http://www.greenpeace.org/international/en/
publications/reports/Swimming-in-Chemicals/
3 Yarns and Fibers Exchange (2011). China’s textiles exports growth
regains momentum in 2010. 8 March 2011.|
http://www.yarnsandfibers.com/news/index_fullstory.php3?id=24553
4 Converse does not have its own CSR policy but adheres to Nike’s policy.
5 Dow Jones Sustainability Index (2010). Sector overview: TEX clothing,
accessories and footwear.
http://www.sustainability-index.com/djsi_protected/Review2010/
SectorOverviews_10/DJSI_TEX_11_1.pdf
6 Puma (2009) “PUMASafe: Handbook of Environmental Standards 2009”
http://safe.puma.com/us/en/category/pumasafe/
7 http://www.adidas-group.com/en/sustainability/Environment/green_
company/default.aspx
8 http://www.nikebiz.com/crreport/content/pdf/documents/en-US/fullreport.pdf
9 http://www.hm.com/filearea/corporate/fileobjects/pdf/en/CSR_
REPORT2010_PDF_1302846254219.pdf
10 http://www.pvh.com/pdf/environmental_policy.pdf

Section 1
1 Circle of Blue (2009). “Water tops climate change as global priority”,
18 August.
http://www.circleofblue.org/waternews/2009/world/waterviews-watertops-climate-change-as-global-priority/
2 Circle of Blue/GlobeScan (2009). Water Issues Research.
http://www.circleofblue.org/waternews/wp-content/uploads/2009/08/
circle_of_blue_globescan.pdf
3 World Water Assessment Programme (2009). The United Nations World
Water Development Report 3: Water in a changing world, Paris: UNESCO
Publishing and London: Earthscan.
http://www.unesco.org/water/wwap/wwdr/wwdr3/
4 For more examples of the costs of industrial pollution on people, planet
and the wider economy, please refer to: Greenpeace International (2011).
Hidden Consequences. The costs of industrial water pollution on people,
planet and profit.
http://www.greenpeace.org/international/en/publications/reports/HiddenConsequences/
5 UNIDO (2003). The United Nations World Water Development Report:
Water for people water for life.
http://portal.unesco.org/en/ev.php-URL_ID=10064&URL_DO=DO_
TOPIC&URL_SECTION=201.htm
6 OECD (2006). Water: The experience in OECD countries, p.39.
http://www.oecd.org/dataoecd/18/47/36225960.pdf
7 World Water Assessment Programme (2009) op cit, p143.
http:// www.unesco.org/water/wwap/wwdr/wwdr3/pdf/WWDR3_Water_
in_a_Changing_World.pdf
8 Powell B (2002). “‘Its All Made in China Now’”, Fortune, 4 March, p.121,
quoted in Harney, Alexandra (2008) The China price; The true cost of
Chinese competitive advantage, London: Penguin Press

102

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9 Karasov C (2000). On a different scale; putting China’s environmental
Crisis in perspective, October 2000, Volume 108, Number 10,
Environmental Health Perspectives.
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1240140/pdf/
ehp0108-a00452.pdf
10 China Institute of Geo-Environment Monitoring (2005). “Seventy per cent
of Rivers and lakes in China are polluted as a result of eight major causes”
(Chinese text).
http://www.cigem.gov.cn/readnews.asp?newsid=5002
11 National Development and Reform Commission (2011). Development
and Reform Commission reports that ¼ of China’s residents have no clean
drinking water, 9 March 2011, Economic Information Daily.
http://politics.people.com.cn/GB/1027/14096289.html
12 20% represents over 5.6m tons of Chemical Oxygen Demand out of a
total of just over 30m tons. The “Chemical Oxygen Demand (COD) test is
commonly used to indirectly measure the quantity of organic compounds
in wastewater or surface water (eg lakes and Rivers), making COD a useful
measure of water quality.
13 China.org.cn (2010). “1st national census on pollution sources
completed”, 9 February.
http://www.china.org.cn/china/2010-02/09/content_19394384.htm
14 Spencer J (2007). “China pays steep price as textile exports boom.
Suppliers to US stores accused of dumping dyes to slash their costs”, Wall
Street Journal, 22 August.
http://online.wsj.com/article/SB118580938555882301.html
15 State Environmental Protection Administration, PR China and
World Bank Rural Development, Natural Resources and Environment
Management Unit (2007). Cost of pollution in China: Economic estimates of
physical damages, p. xvi.
http://web.worldbank.org/WBSITE/EXTERNAL/COUNTRIES/
EASTASIAPACIFICEXT/EXTEAPREGTOPENVIRONMENT/0,,contentMDK:2
1252897~pagePK:34004173~piPK:34003707~theSitePK:502886,00.html
16 Now the Ministry of Environmental Protection.
17 Agence France Press (2006). “China’s environment reaches critical point:
Industrialization moving too rapidly increases pollution”, Vancouver Sun, 14
November, cited in Harney Alexandra (2008), op cit p94.
18 Responsible Research (2010). Water in China: Issues for responsible
investors, February 2010, p46.
http://www.asiawaterproject.org/wp-content/uploads/2009/12/WATERIN-CHINA-Issues-for-Responsible-Investors-FEB2010.pdf
19 State Environmental Protection Administration and World Bank (2007) op cit.
20 The Stockholm Convention is a global treaty to protect human health
and the environment from the effects of Persistent Organic Pollutants
(POPs), also known as the POPs Convention, and POPs treaty. It was
adopted on 23 May 2001 and entered into force on 17 May 2004. It
requires Parties to take measures to eliminate or reduce the release of
POPs into the environment. Initially, 12 POPs were given priority (the ‘dirty
dozen’); those listed in Annex A are to be prohibited/eliminated EXCEPT
as allowed by Annex A, including the chemicals Aldrin, Chlordane,
Dieldrin, Endrin, Heptachlor, Hexachlorobenzene, Mirex, Toxophene,
and PCBs. The production and use of DDT, is to be restricted rather than
eliminated. The requirement for POPs which are byproducts (dioxins,
furans, hexachlorobenzene and PCBs) are that each Party “shall, at a
minimum reduce the total releases derived from anthropogenic sources
of each of the chemicals … with the goal of their continuing minimization
and, where feasible, ultimate elimination. The Convention text was
amended in 2009 to include nine new POPs added to its Annexes A, B
and C, including perfluorooctane sulfonic acid (PFOS) and two brominated
flame retardants. The Convention is administered by the United Nations
Environment Programme and is based in Geneva, Switzerland. For full text
of the convention see: http://chm.pops.int/Convention/tabid/54/language/
en-US/Default.aspx .

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

21 Greenpeace International (2006). “What are Persistent Organic
Pollutants?”, 10 April
http://www.greenpeace.org/international/campaigns/toxics/toxichotspots/what-are-persistent-organic-po/
22 Greenpeace International (2006), op cit.
23 Guangdong Statistical Yearbook 2008 statistics, cited in Hong Kong Trade
Development Council (2008). “Market Profiles on Chinese Cities and Provinces”
http://info.hktdc.com/mktprof/china/prd.htm
24 China Digital Times (2009). China Revamping its Key Southern Factory
Region, 9 January 2009.
http://chinadigitaltimes.net/2009/01/china-revamping-its-key-southernfactory-region/
25 Xinhua (2008). “City water supply resumes after pollution scare”, China
Daily, 18 February.
http://www.chinadaily.com.cn/china/2008-02/18/content_6461086.htm
26 southcn.com (2003). “Planning scheme for water protection areas of
drinking water for the Pearl River Delta” (Chinese text), 10 October.
http://www.southcn.com/news/gdnews/minxin/qw/200310100867.htm
27 Ministry of Water Resources, data released between 2000 and 2007
(Chinese text).
http://www.pearlwater.gov.cn/xxcx/szygg/index.htm
28 Statistics Bureau of Guangdong Province (2000 – 08). GD Statistics,
data compiled for the 2000–08 Guangdong Statistical Yearbooks
29 Statistics Bureau of Guangdong Province (2008) 2008 Guangdong
Statistical Yearbook
30 Enright MJ, Scott EE, Invest Hong Kong (2005). The Greater Pearl River
Delta, p6.
http://www.investhk.gov.hk/doc/InvestHK_GPRD_Booklet_English571.pdf
31 Greenpeace (2010). Poisoning the Pearl: An investigation into industrial
water pollution in the Pearl River Delta, 2nd edition.
http://www.greenpeace.org/raw/content/eastasia/press/reports/pearlriver-report-2.pdf
32 Yang G, Weng L & Li L (2007). Yangtze Conservation and Development
Report 2007, Wuhan: Changjiang Press.
33 Yang G, Ma C & Chang S (2009). Yangtze Conservation and
Development Report, Wuhan: Changjiang Press
34 Yang G, Weng L & Li L (2007) op cit.

References

greenpeace.to/publications/swimming-in-chemicals.pdf)
as follows:
(1) For PFOS see: Wang T et al (2009). Perspective on the Inclusion of
Perflourooctane Sulfonate into the Stockholm Convention of Persistent
Organic Pollutants, Environ. Sci. Technol. 2009, 43, 5171 – 5175: and
POPRC (2008). Consideration of new information on perfluorooctane
sulfonate (PFOS); UNEP/POPS/POPRC.4/INF/17; Stockholm
Convention on Persistent Organic Pollutants, August 2008.
For alkylphenols see:
Brigden K et al (2010) op cit; and
Zhang Ri-xin, Zhang Xiao-dong (2008). Supply and Demand of Phenol
and Development in China.Chemical Industry. 26(6).
(2) Brigden K et al (2010) op cit.
(3) Shao et al (2005) op cit.
(4) Brigden K et al (2010) op cit.
(5) Pan G & You C (2010). Sediment-water distribution of
perfluorooctane sulfonate (PFOS) in Yangtze River Estuary.
Environmental Pollution 158(5): 1363-136
(6) Jin YH, Liu W, Sato I, Nakayama SF, Sasaki K, Saito N & Tsuda
S (2009). PFOS and PFOA in environmental and tap water in China.
Chemosphere 77(5): 605-61; and
Mak YL, Taniyasu S, Yeung LWY, Lu G, Jin L, Yang Y, Lam PKS,
Kannan K & Yamashita N (2009). Perfluorinated compounds in tap
water from China and several other countries. Environmental Science &
Technology 43(13): 4824–4829
41 Brigden K et al (2010) p3 op cit.
42 Xie Chunlin in an interview conducted by Greenpeace Southeast Asia on
10 July, 2010. at Yanglingang, Fuqiao, Taicang, Jiangsu province.
43 Lacasse K & Baumann W (2004). Textile chemicals: Environmental data
and facts, Berlin, London: Springer, p81.
44 Greer L, Keane SE & Lin X (2010). NRDC’s ten best practices for textile
mills to save money and reduce pollution: A practical guide for responsible
sourcing, New York: Natural Resources Defense Council, p3.
http://www.nrdc.org/international/cleanbydesign/files/rsifullguide.pdf
45 Swedish Chemical Agency (1997). Chemical in Textiles. Solna, Swedish
Chemical Agency, p.19.
http://www.kemi.se/upload/Trycksaker/Pdf/Rapporter/Report_5_97_
Chemicals_in_textiles.pdf

35 2005 data in Li and Fung Research Centre (2006). Industrial clusters in
Yangtze River Delta (YRD).
http://www.idsgroup.com/profile/pdf/industry_series/LFIndustrial3.pdf

46 Section 3 gives examples hazardous substances used in textile
processing.

36 China Daily (2006). “Yangtze River ‘cancerous’ with pollution”, 30 May.
http://www.chinadaily.com.cn/china/2006-05/30/content_604228.htm

47 Swedish Chemical Agency (1997). Chemical in Textiles. Solna, Swedish
Chemical Agency, p19.
http://www.kemi.se/upload/Trycksaker/Pdf/Rapporter/Report_5_97_
Chemicals_in_textiles.pdf

37 Wang Qian, He Dan (2010). “Clean-up bid for Yangtze set to begin”,
China Daily, 1 September.
http://www.chinadaily.com.cn/usa/2010-09/01/content_11239709.htm
38 Ministry of Environmental Protection (2009). 2008 China Statistical
Yearbook on the Environment, China Statistics Press, ISBN:
9787503758461
39 Wu B, Zhang X, Yasun A, Zhang Y, Zhao D, Ford T & Cheng S (2009).
“Semi-volatile organic compounds and trace elements in the Yangtze River
source of drinking water”, Ecotoxicology, vol 18, pp707-714
40 The information in Figure 1 is taken from Brigden K, Allsop M & Santillo
D (2010). Swimming in chemicals: Perfluorinated chemicals, alkylphenols
and metals in fish from the upper, middle and lower sections of the
Yangtze River, China, Amsterdam: Greenpeace International (http://www.

48 Based on Figure 3 in Zhang Y (2009) op cit.
49 Greer L, Keane SE & Lin X (2010) p3 op cit.
50 Yarns and Fibers Exchange (2011). China’s textiles exports growth
regains momentum in 2010. 8 March 2011.|
http://www.yarnsandfibers.com/news/index_fullstory.php3?id=24553
51 Zhang Y (2009) p19 op cit.
52 Business for Social Responsibility (2008) p2 op cit.
53 China Textile City Hangzhou, Zeijang textile industry overview.
http://www.qfcrf.com/html/english/Protection.html (accessed June 2011)

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

103

References (continued)
54 China Textile Magazine (2010). “Expansion of textile industrial cluster in
China”, 5 March.
http://chinatextile.360fashion.net/2010/03/expansion-of-textile-industria.
php

70 Allsopp M, Costner P & Johnston P (2001). Incineration and human
health: State of knowledge of the impacts of waste incinerators on human
health, Amsterdam: Greenpeace International
http://www.greenpeace.to/publications/euincin.pdf

55 China Textile Magazine (2010) op cit.

71 Labunska I, Brigden K, Santillo D, Kiselev A & Johnston P (2010).
Russian Refuse 2: An update on PBDEs and other contaminants detected
in St-Petersburg area, Russia, Technical Note 04/2010, Exeter: Greenpeace
Research Laboratories.
http://www.greenpeace.to/publications/russian-refuse-2english%5B1%5D.pdf

56 Li Fung Research Centre (2010). Update on Industrial Clusters, June,
Issue 6. Industrial Cluster Series
http://www.lifunggroup.com/eng/knowledge/research.
php?report=industrial
57 Finnish Environment Institute (2010). Releases from the use of
products, Case Study 10, “Releases from the use phase of textile and
leather products” p4, Finnish Environment Institute, Centre for Sustainable
Consumption and Production, Environmental Performance Unit.
http://www.ymparisto.fi/download.asp?contentid=124343&lan=fi

Section 2

58 Li Fung Research Centre (2010). China’s apparel market 2010, Industry
Series, October, Issue 16.
http://www.lifunggroup.com/eng/knowledge/research.php?report=industry

1 In our research we also sampled 7 other suppliers for which a chain of
evidence could not be completed. Therefore, the outcome of this research
is not relevant to this publication.

59 Swedish Chemical Agency (1997) op cit p18.
60 Business for Social Responsibility (2008). Water management in China’s
apparel and textile factories, p2.
http://www.bsr.org/en/our-insights/report-view/water-management-inchinas-apparel-and-textile-factories

2 Brigden K, Labunska I, Pearson M, Santillo D & Johnston P (2011).
Investigation into hazardous chemicals discharged from two textile
manufacturing facilities, China, 2011, Technical Note 01/2011, Exeter:
Greenpeace Research Laboratories
http://www.greenpeace.org/international/Global/international/publications/
climate/2011/TextileManufacture_China.pdf.

61 Responsible Research (2010) op cit p80.

3 Brigden et al (2011) op cit.

62 Greenpeace (2010), Poisoning the Pearl, op cit.

4 Youngor Group Co Ltd is known as the brand name Youngor and as the
supplier name Youngor Textile Complex.

63 See Section 2 Box 2.1 for details on nonylphenol and Appendix 3,
Quinone and di-ketone derivatives for information on benzophenone
derivatives.
64 Xinhua Net Guangdong (2008). “Qingxin achieved production growth
without increasing pollution” (Chinese text), 5 March.
http://www.gd.xinhuanet.com/sungov/2008-03/05/content_12619360.
htm
65 Personal communication to Greenpeace, May 2009 published in
Greenpeace 2010, Poisoning the Pearl, page 7 op cit.
66 Personal conversation to Greenpeace, May 2010. Published in
Greenpeace East Asia (2010). The dirty secret behind jeans and bras,
December 2010.
http://www.greenpeace.org/eastasia/news/textile-pollution-xintang-gurao.
67 Law of the Peoples’ Republic of China on Prevention and Control of
Water Pollution, 87th Order of Chinese President. The latest version was
approved on 28 February 2008 by National Peoples’ Congress (NPC)
Standing Committee and came into force on 1 June 2008.
http://www.gov.cn/flfg/2008-02/28/content_905050.htm
68 There is a cleaner production standard for the textile industry “HJ/T 185-2006
Cleaner Production Standard – Textile Industry (dyeing and finishing of cotton)”,
published by MEP. There is also a list of key hazardous substances for clean
production auditing, which list some hazardous wastes, such as “dyes and paints
waste”; for each hazardous substance/waste, there are related industries. In
addition, the Ministry of Industry and Information Technology (MIIT) has published
a “Clean Production Technology promotion plan for Textile, Dyeing and Finishing
industry”, which suggests several technologies to save the use of chemicals or
water. However, none of the above measures is mandatory and although general
reference to hazardous chemicals is made, there are no specific lists of chemicals
to be avoided or eliminated. The State Council has also asked the Textile industry
to eliminate some outdated technologies.
69 Greenpeace (2010) pp37 – 40 op cit.

104

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72 Greenpeace (2011). Hidden Consequences, op cit.

5 http://www.youngor.com/
6 Youngor Group Ltd (2008). “Branded garments business review”
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40&cid=200811211010001550
7 http://www.youngor.com/youngor_sub/index.
do?sid=200903130340424300
8 Youngor Group Ltd (2008) “Environmental protection”
http://en.youngor.com/responsibility.do?action=display&
cid=200811190221474000
9 Brigden et al (2011) op cit.
10 Adidas Group (2011) “Green company”.
http://www.adidas-group.com/en/sustainability/Environment/green_
company/default.aspx
11 Youngor Group Ltd (2008) “Environmental protection”.
http://en.youngor.com/responsibility.do?action=display&
cid=200811190221474000
12 Puma (2009) “PUMASafe: Handbook of environmental standards”, p12.
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handbook_Environmental.pdf
13 Grupo Cortefiel (2010). External Code of Conduct.
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14 Nike Inc Corporate Responsibility Report FY 07 08 09, p38.
http://www.nikebiz.com/crreport/content/pdf/documents/en-US/fullreport.pdf
15 Lacoste Press Kit.
http://www.lacoste.com/library/download/pdf/LACOSTE_presskit_en.pdf

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

16 H&M Conscious Actions Sustainability Report (2010).
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17 Phillips-Van Heusen, Environmental Statement.
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18 Brigden K et.al (2011) op cit. See discussion on the presence of
nonylphenols and perflourinated chemicals in samples results from Pipe 1
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19 So MK, Miyake Y, Yeung WY, Ho YM, Taniyasu S, Rostkowski P,
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26 So MK et al (2007) op cit.
27 Jin YH, Liu W, Sato I, Nakayama SF, Sasaki K, Saito N & Tsuda S (2009).
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References (continued)
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68 Rudel RA, Camann DE, Spengler JD, Korn LR & Brody JG (2003).
“Phthalates, alkylphenols, pesticides, polybrominated diphenyl ethers,
and other endocrine-disrupting compounds in indoor air and dust”,
Environmental Science and Technology, vol 37, no 20, pp4543-4553
69 Rudel et al (2003) op cit.

50 Zhongshang Research Institute of Environmental Protection (2008).
“Expansion Project of Well Dyeing Factory Limited” (Chinese text.
Environmental Influence Assessment Report, Copy on Approval (ZRIEP)

70 Saito I, Onuki A & Seto H (2004). “Indoor air pollution by alkylphenols in
Tokyo”, Indoor Air, vol 14, no 5, pp325-332

51 Well Dyeing (2010). Well Dyeing company website (Chinese text).
http://www.welldyeing.com

72 Lopez-Espinosa MJ, Freire C, Arrebola JP, Navea N, Taoufiki J,
Fernandez MF, Ballesteros O, Prada R & Olea N (2009). “Nonylphenol and
octylphenol in adipose tissue of women in Southern Spain”, Chemosphere,
vol 76, no 6, pp847-852

52 Other samples (of discharged water and river sediments) were collected in
the vicinity of this site, as detailed in the Technical Note, Brigden K (2011) op cit.
53 Li Ning Company (2011). “Vision, mission, core value”.
http://www.lining.com/EN/company/inside-1_3.html
54 https://afcares.anfcorp.com/anf/intranet/site/afcares/sustainability
55 Meters/bonwe (2008). Meters/bonwe 2008 CSR Report, p8.
56 For example, see Spencer J (2007) op cit.
57 OSPAR (2001). Nonylphenol/nonylphenolethoxylates, OSPAR Priority
Substances Series, London: OSPAR Commission.
http://www.ospar.org/documents/dbase/publications/p00136_BD%20
on%20nonylphenol.pdf
58 Guenther K, Heinke V, Thiele B, Kleist E, Prast H & Raecker T (2002).
“Endocrine disrupting nonylphenols are ubiquitous in food”, Environmental
Science and Technology, vol 36, no 8, pp1676-1680
59 Fu M, Li Z & Wang B (2008). “Distribution of nonylphenol in various
environmental matrices in Yangtze River estuary and adjacent areas”,
Marine Environmental Science, vol 27, no 6, pp561-556
60 Shue MF, Chen FA & Chen TC (2009). “Total estrogenic activity and
nonylphenol concentration in the Donggang River, Taiwan”, Environmental
Monitoring and Assessment, 168(1-4): 91-101
61 David A, Fenet H & Gomez E (2009). “Alkylphenols in marine
environments: Distribution monitoring strategies and detection
considerations”, Marine Pollution Bulletin, vol 58, no 7, pp953-960

71 OSPAR (2001) op cit.

73 Jobling S, Reynolds T, White R, Parker MG & Sumpter JP (1995).
“A variety of environmentally persistent chemicals, including some phthalate
plasticizers, are weakly estrogenic”, Environmental Health Perspectives,
vol 103, no 6, pp582-587
74 Jobling S, Sheahan D, Osborne JA, Matthiessen P & Sumpter JP (1996).
“Inhibition of testicular growth in rainbow trout (Oncorhynchus mykiss)
exposed to estrogenic alkylphenolic chemicals”, Environmental Toxicology
and Chemistry, vol 15, no 2, pp194-202
75 Blake CA, Boockfor FR, Nair-Menon JU, Millette CF, Raychoudhury SS &
McCoy GL (2004). “Effects of 4-tert-octylphenol given in drinking water for 4
months on the male reproductive system of Fischer 344 rats”, Reproductive
Toxicology, vol 18, no 1, pp43-51
76 Chitra KC, Latchoumycandane C & Mathur PP (2002). “Effect of
nonylphenol on the antioxidant system in epididymal sperm of rats”,
Archives of Toxicology, vol 76, no 9, pp545-551
77 Adeoya-Osiguwa SA, Markoulaki S, Pocock V, Milligan SR & Fraser LR
(2003). “17-betaestradiol and environmental estrogens significantly affect
mammalian sperm function”, Human Reproduction, vol 18, no 1, pp100-107
78 Harreus UA, Wallner BC, Kastenbauer ER & Kleinsasser NH (2002).
“Genotoxicity and cytotoxicity of 4-nonylphenol ethoxylate on lymphocytes
as assessed by the COMET assay”, International Journal of Environmental
Analytical Chemistry, vol 82, no 6, pp395-401

62 Micic V & Hofmann T (2009). “Occurrence and behaviour of selected
hydrophobic alkylphenolic compounds in the Danube River”. Environmental
Pollution, vol 157, no 10, pp2759-2768

79 Iwata M, Eshima Y, Kagechika H & Miyaura H (2004). “The endocrine
disruptors nonylphenol and octylphenol exert direct effects on T cells to
suppress Th1 development and enhance Th2 development”, Immunology
Letters, vol 94, nos 1-2, pp135-139

63 Ying GG, Kookana RS, Kumar A & Mortimer M (2009). “Occurrence
and implications of estrogens and xenoestrogens in sewage effluents
and receiving waters from South East Queensland”, Science of the Total
Environment, vol 407, no 18, pp5147-5155

80 Ministry of Environmental Protection (2011). List of Toxic Chemicals
Severely Restricted for Import and Export in China.
http://www.crc-mep.org.cn/news/NEWS_DP.aspx?TitID=267&T0=10000&
LanguageType=CH&Sub=125

64 Yu Y, Zhai H, Hou S & Sun H (2009). “Nonylphenol ethoxylates and
their metabolites in sewage treatment plants and Rivers of Tianjin, China”,
Chemosphere, vol 77, no 1, pp1-7

81 The Contracting Parties to the Oslo and Paris Conventions are Belgium,
Denmark, the European Union, Finland, France, Germany, Iceland, Ireland,
the Netherlands, Norway, Portugal, Spain, Sweden and the UK.

65 Fries, E. and Püttmann, W. (2004) “Occurrence of 4-nonylphenol in rain
and snow”, Atmospheric Environment, vol 38, no 13, pp.2013-2016

82 PARCOM (1992). “PARCOM Recommendation 92/8 on nonylphenolethoxylates”, London: OSPAR Commission

66 Peters RJB, Beeltje H & Van Delft RJ (2008). “Xeno-estrogenic
compounds in precipitation”, Journal of Environmental Monitoring, vol 10,
pp760-769

83 OSPAR (1998). OSPAR Strategy with Regard to Hazardous Substances,
OSPAR 98/14/1 Annex 34

106

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Greenpeace
International

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Unravelling the corporate
connections to toxic water
pollution in China

84 EU (2008). Directive 2008/105/EC Of The European Parliament And
Of The Council of 16 December 2008 on environmental quality standards
in the field of water policy, amending and subsequently repealing Council
Directives 82/176/EEC, 83/513/EEC, 84/156/EEC, 84/491/EEC,
86/280/EEC and amending Directive 2000/60/EC, Official Journal L348,
24/12/2008, pp87-94
85 EU (2003). Directive 2003/53/EC Of The European Parliament And Of
The Council Of 18 June 2003 Amending For The 26th Time Council Directive
76/769/EEC Relating To restrictions on the marketing and use of certain
dangerous substances and preparations (nonylphenol, nonylphenol ethoxylate
and cement) Official Journal L178/24, 17/7/2003 http://eur-lex.europa.eu/
LexUriServ/LexUriServ.do?uri=OJ:L:2003:178:0024:0027:EN:PDF

Section 3
1 Arora A (1999). “The chemical industry: from the 1850s until today”,
Business Economics, 1 October.
http://www.allbusiness.com/finance/322115-1.html
2 Getliff JM & James SG (1996). “The replacement of alkyl-phenol ethoxylates
to improve the environmental acceptability of drilling fluid”, Society of
Petroleum Engineers Inc Health, Safety and Environment in Oil and Gas
Exploration and Production Conference, 9–12 June, New Orleans. http://
www.onepetro.org/mslib/servlet/onepetropreview?id=00035982&soc=SPE
3 Hussain S (1987). “A history of halogenated flame retardants”, in
Seymour, R.B and Deanin, R.D., History of polymer composites, Utrecht:
VNU Science Press BV
4 Paul AG, Jones K & Sweetman AJ (2009). “A first global production,
emission, and environmental inventory for perfluorooctane sulfonate”,
Environmental Science & Technology, vol 43, no 2, pp386–392
http://pubs.acs.org/doi/abs/10.1021/es802216n
5 Calafat AM, Wong L-Y, Kuklenyik Z, Reidy JA & Needham LL (2007).
Polyfluoroalkyl Chemicals in the U.S. Population: Data from the National
Health and Nutrition Examination Survey (NHANES) 2003–2004 and
Comparisons with NHANES 1999–2000 Environ Health Perspect. 2007
November; 115(11): 1596–1602. Published online 2007 August 29. doi:
10.1289/ehp.10598.
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2072821/
6 Gereffi G & Memedovic O (2003). The global apparel value chain: What
prospects for upgrading by developing countries, Sectoral Studies Series,
Vienna: UNIDO
7 China Textile Magazine (2010). Expansion of Textile Industrial Clusters, 5
March 2010.
http://chinatextile.360fashion.net/2010/03/expansion-of-textile-industria.
php
8 Responsible Research (2010) op cit, p80
9 Responsible Research (2010) op cit, p80
10 PricewaterhouseCoopers (2008). Global Sourcing: Shifting Strategies, A
Survey of Retail and Consumer Companies.
http://www.pwc.com/gx/en/retail-consumer/sourcing/global-sourcingshifting-strategies.html
11 Spencer J (2007) op cit.
12 Spencer J (2007) op cit.
13 Textile Exchange (n.d.) “Industry overview”.
http://www.teonline.com/industry-overview.html

References

14 World Trade Organisation (2011). Regional integration and the African
textile industry, part 5: Analysis of EAC textiles sector – The African textiles
industry under siege, WTO Updates for Business.
http://www.intracen.org/BB-2011-03-07-Regional-Integration-and-theAfrican-Textile-Industry/
15 World Trade Organisation (2010). International Trade Statistics 2010,
Merchandise trade by product.
http://www.wto.org/english/res_e/statis_e/its2010_e/its10_toc_e.htm,
http://www.wto.org/english/res_e/statis_e/its2010_e/its10_merch_trade_
product_e.pdf
16 Finnish Environment Institute (2010). Releases from the use of
products, Case Study 10, “Releases from the use phase of textile and
leather products” p4, Finnish Environment Institute, Centre for Sustainable
Consumption and Production, Environmental Performance Unit.
http://www.ymparisto.fi/download.asp?contentid=124343&lan=fi
17 World Trade Organisation (2010) op cit.
18 Cao N, Zhang Z, Kin MT & Keng PN (2008). “How Are Supply Chains
Coordinated? An empirical observation in textile-apparel businesses”,
Journal of Fashion Marketing and Management, vol 12, pp384-397
19 Business for Social Responsibility (2008) op cit.
20 Adapted from UNEP, DTIE/Chemicals Branch (2011).
The Chemicals in Products Project: Case study of the textile sector, January
2011.
http://www.chem.unep.ch/unepsaicm/cip/Documents/CaseStudies/
CiP%20textile%20case%20study%20report_21Feb2011.pdf
21 UNEP, DTIE/Chemicals Branch (2011) op cit.
22 Euromonitor International (2010). Market Share Apparel 2003 – 2008
http://www.euromonitor.com/clothing-and-footwear
23 Hoover’s Inc (2010). Industry profile: Apparel manufacture.
http://www.hoovers.com/industry/apparel/1161-1.html
Registration required.
24 Hoover’s Inc (2010) op cit.
25 Euromonitor International (2010) op cit.
26 Cao N et al (2008) op cit.
27 Lacasse K & Baumann W (2004). Textile chemicals: Environmental data
and facts, Berlin, London: Springer, p81
28 Euromonitor (2010) op cit.
29 Casseres BG, Petkova P, Pattabiraman S, Nike Inc. & the Athletic
Footwear Industry Strategy and Competition Analysis, 19 May 2010, p15
http://www.scribd.com/doc/38643840/Nike-Strategy-Analysis-FinalJun-2010
30 Wikinvest (n.d.) “Puma AG Rudolf Dassler Sport (PUM-FF)”, citing
Dolleschal, Christoph (2008). “Adidas”, Equity Research, Commerzbank,
28 February.
http://www.wikinvest.com/stock/Puma_AG_Rudolf_Dassler_
Sport_%28PUM-FF%29.
31 Locke RM (2003). “The promise and perils of globalization: The case of
Nike” pp.4-5 in Kochan TA & Schmalensee R (eds.) Management: Inventing
and Delivering Its Future, Cambridge, Mass.: MIT Press,
32 Now, up to 74% of its total production is produced in Asia with 308
production sites in China of a total of 675 sites, Adidas Group, 2009,
Sustainability Review, p73.
http://www.adidasgroup.com/en/SER2009/pdfs/adidas_online_
review_2009.pdf

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107

References (continued)
33 Economist (2007). In the steps of Adidas, How smaller firms can survive
globalisation, Feb 8th 2007 | from the print edition.
http://www.economist.com/node/8621794
34 Clean Clothes Campaign (2004). Sportswear Industry Data and
Company Profiles, Background information for the Play Fair at the Olympics
Campaign. March 1, 2004 p116.
http://www.fairolympics.org/background/Company_Profiles.pdf
35 See for example Locke R et al (2007). “Beyond corporate codes of
conduct: Work organization and labour standards at Nike’s suppliers”,
International Labour Review, vol 146, no 1, p5
36 Oxfam (2006). Offside! Labour rights and sportswear production in Asia,
summary
http://www.oxfam.org.uk/resources/policy/trade/downloads/offside_
sportswear_summ.pdf

non-toxic in use and disposal and using them in manufacturing products
does not involve toxic releases or damaging ecosystems.” However,
this statement does not specify preventing the discharge of hazardous
substances to water; in addition, there is no implementation plan for how
this is to be achieved.
49 Puma (2008). PUMA Vision Sustainability Report 2007/2008
http://images.puma.com/BLOG_CONTENT/puma_safe/PUMA_
Sustainability_Report_2007-2008.pdf
50 Puma (2009). “PUMASafe: Handbook of Environmental Standards
2009”, p12
51 Puma (2009). “PUMASafe: Handbook of Environmental Standards
2009”, p7
52 Or the use of related perfluorinated chemicals that can result in the
presence of PFOS or PFOA in wastewater.

37 Dow Jones Sustainability Index (2010). Sector overview: TEX clothing,
accessories and footwear
http://www.sustainability-index.com/djsi_protected/Review2010/
SectorOverviews_10/DJSI_TEX_11_1.pdf (requires registration)

53 Nike Inc (2010). “Nike restricted substances list (RSL) and sustainable
chemistry guidance (SCG)”, pp49–50

38 However, not all companies in the sector take such a proactive approach
to CSR and sustainability. Some of the brands featured in our investigation
– such as Li Ning, Youngor and Bauer Hockey – have limited or no reporting
on CSR or sustainability issues. Converse does not have its own CSR policy
but adheres to Nike’s policy. (See Appendix 1 for further details).

55 Puma (2009). “PUMASafe: Handbook of Environmental Standards
2009”, op cit, which includes its Restricted Substances List

39 Nike Inc (2010). “Nike restricted substances list (RSL) and sustainable
chemistry guidance (SCG)”.
http://www.nikebiz.com/responsibility/considered_design/documents/
RSL_Finished_Product.pdf
40 Adidas Group (2010) “Adidas group policy for the control and monitoring
of hazardous substances”.
http://www.adidas-group.com/en/sustainability/assets/Guidelines/
A01_Sept_2010.pdf
41 Puma (2009) “PUMASafe: Handbook of Environmental Standards 2009”
(includes the company’s Restricted Substances List) .
http://safe.puma.com/us/en/category/pumasafe/
42 Such as limits on biological oxygen demand, chemical oxygen demand,
suspended solids etc.
43 Nike Inc (2009). Corporate Responsibility Report FY 07 08 09, pp80–83
http://www.nikebiz.com/crreport/content/pdf/documents/en-US/fullreport.pdf
44 Nike Inc (2010). “Nike restricted substances list (RSL) and sustainable
chemistry guidance (SCG)”, pp42-48
45 Adidas Group (2010). “Environmental Statement 2010”, p10.
http://www.adidas-group.com/en/sustainability/assets/environmental_
statements/Environmental_Statement_2010_english.pdf
46 Adidas Group (2011). “Green Company”.
www.adidas-group.com/en/sustainability/Environment/green_company/
default.aspx
47 Relative cuts of energy use are as a proportion of production or
operations, compared to absolute cuts which set a percentage reduction of
the total quantity of energy used.
48 Adidas restricts a range of heavy metals in wastewater discharges:
see Adidas Group (2010). “Environmental Guidelines 2010”, p22.
www.adidas-group.com/en/sustainability/assets/Guidelines/
Environmental_Guidelines_Jan_2010.pdf.
At the end of the Environmental Guidelines (p.37) there is a section on
Chemicals and Restricted Substances, which requires suppliers to avoid
the use of substances listed in its Restricted Substances List (HS-A01).
Group Policy and to “Ensure that materials and components supplied are

108

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

54 Adidas Group (2010). “Adidas group policy for the control and
monitoring of hazardous substances”

56 European Union REACH Regulation (EC) No 1907/2006 Annex XVII.
Nonylphenols and nonylphenol ethoxylates are restricted to 1,000ppm
preparation in products. PFOS is restricted to 1µg/m2. The Canadian
Environmental Protection Act 1999, Registration SOR 2008/178 prohibits
the manufacture, use, sale, offer for sale and import of PFOS, as well as
products containing PFOS, but does not specify a limit.
57 See for example the search for solutions through the collective industry
platform International Electronics Manufacturing Initiative (iNEMI). iNEMI
has published a white paper that reports progress made by its members
towards removing halogenated flame retardants and PVC from desktop and
laptop computers: iNEMI (2010) iNEMI timeline for HFR-free electronics and
PVC-free cabling for notebook and desktop products.
http://www.inemi.org/cms/newsroom/PR/2010/PR112910.html
58 Greenpeace International (2010). Electronics industry – Milestones on
the road to greener electronics
http://www.greenpeace.org/international/Global/international/publications/
toxics/2011/Achievements%203-%20Industry%20then%20and%20now.
pdf
59 European Commission (2003). “Directive 2002/95/EC of the European
Parliament and the Council, 27 January 2003, on the restriction of the use
of certain hazardous substances in electrical and electronic equipment.
http://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=OJ:L:2003:037:00
19:0023:EN:PDF.” Official Journal L037: 19-23.
60 European Commission (2003a). “Directive 2002/96/EC on Waste
Electrical and Electronic Equipment (WEEE)”, http://eur-lex.europa.eu/
LexUriServ/LexUriServ.do?uri=OJ:L:2003:037:0024:0038:en:PDF Official
Journal L37/24 13.2.2003
61 One of the cornerstones of the WEEE Directive is Individual Producer
Responsibility (IPR), which establishes that the producer pays for the costs,
environmental and otherwise, of managing its own obsolete products,
from collection to re-use, recycling and disposal. The principle is that
the incentive is on the producer to redesign its products with the endof-life consequences in mind, and in particular to phase out hazardous
substances that make the recycling process difficult and potentially
dangerous.
62 WTO (2010). International Trade Statistics 2010 op.cit.
63 Environment Canada (2007). “Progress report – P2 planning and textile
mills that use wet processing”.
http://www.ec.gc.ca/planp2-p2plan/default.asp?lang=En&n=3944D8AC-1

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

References

64 XCG Consultants (2006). Best management practices, textiles
sector: Nonylphenol and its ethoxylates and chromium, for Ministry of the
Environment, Canada, 3-1474-17-03/R147170300textiles.doc
http://www.cwwa.ca/pdf_files/Source%20Control%20-%20Ontario%20
textile.pdf

81 Danish Environmental Protection Agency (2005). More environmentally
friendly alternatives to PFOS-compounds and PFOA, Environmental Project
No 1013.
http://ww2.mst.dk/common/Udgivramme/Frame.asp?http://www2.mst.
dk/udgiv/publications/2005/87-7614-668-5/html/helepubl_eng.htm

65 XCG Consultants (2006) op cit.

82 Astrup Jensen A, Brunn Poulsen P & Bossi, R (2008) op cit.

66 Ishikawa Y, Glauser J & Janshekar H (2008). Chemical Economics
Handbook: Dyes, SRI Consulting in Chemical Industries Newsletter, March
2008.
http://www.sriconsulting.com/nl/Public/2008Mar.pdf

83 Greenpeace Germany, personal communication, April 2011.

67 North Carolina Department of Environmental Management (1982).
Incorporating the Pollution Prevention Pays concept: A plan of action.
Raleigh, NC: North Carolina Department of Environmental Management
68 Environmental Protection Agency (2010). Nonylphenol (NP) and
nonylphenol ethoxylates (NPEs) action plan.
http://www.epa.gov/oppt/existingchemicals/pubs/actionplans/
RIN2070-ZA09_NP-NPEs%20Action%20Plan_Final_2010-08-09.pdf
69 Personal communiciation from Sam Moore, formerly of Burlington
Research Incorporated, the primary consulting firm working with the State
on the project.
70 Moore SB & Ausley LW (2004). Systems thinking and green chemistry in
the textile industry: concepts, technologies and benefits, Journal of Cleaner
Production, 12: 596.

84 TEGEWA (2009). Abwassereinträge von per/ Abwassereinträge von per/
polyfluorierten Chemikalien (PFC) in der Textilindustrie, 19June, Berlin http://
www.umweltbundesamt.de/wasser-und-gewaesserschutz/publikationen/
fgpfc/abwassereintraege_von_pfc_in_textilindustrie-schroeder.pdf
85 Rudolf Group (n.d.) “Bionic-finish: The water-, oil- and soil-repellent
textile impregnation”.
http://www.rudolf.de/products/details-brochure.htm?year=2004&ri=
200416
86 ie fluorocarbons or fluorotelomers
87 Astrup Jensen A, Brunn Poulsen P & Bossi R (2008) op cit.
88 Schultz P.-E & Norin H (2006) op cit.
89 Swedish Society for Nature Conservation (2008). T-shirts with a murky
past, Report 8 9629
http://www.naturskyddsforeningen.se/upload/report-t-shirts-with-amurky-past.pdf

71 Personal communication from Sam Moore (see above), confirmed by
personal communication from Gary Hunt of the NC Pollution Prevention
program (August 2010).

90 Swedish Society for Nature Conservation (2008) op cit.

72 Conway P et al (2003). The North Carolina Textiles Project: An Initial
Report, U. NC at Chapel Hill.
http://www.unc.edu/~pconway/Textiles/nctp_tatm_rev.pdf

92 iNEMI (2010) op cit.

73 For more information see Box 2.3, Section 2.

Section 4

74 Environmental Working Group (2003). PFCs: Global Contaminants,
executive summary: “Consumers instantly recognize them as household
miracles of modern chemistry – Teflon, Scotchgard, Stainmaster, Gore-Tex”
http://www.ewg.org/reports/pfcworld

1 Lacasse K & Baumann W (2004) op cit, p81.

75 Environmental Working Group (2008). Credibility gap: Toxic chemicals
in food packaging and DuPont’s greenwashing, executive summary: “How
green is DuPont’s replacement for Teflon chemical”
http://www.ewg.org/reports/teflongreenwash
76 Bao J, Liu W, Liu L, Jin Y, Ran X & Zhang Z (2010). Perfluorinated
compounds in urban river sediments from Guangzhou and Shanghai of
China. Chemosphere 80(2): 123-13
77 Schultz P.-E & Norin H (2006). Fluorinated pollutants in all-weather
clothing, Friends of the Earth Norway, Report 2/2006.
http://naturvern.imaker.no/data/f/0/75/41/1_2401_0/2_Fluorinated_
pollutants_in_all-weather_clothing.pdf

91 iNEMI (2010) op cit.

2 Harremoes P, Gee D, MacGarvin M et al (eds.) (2001). Late lessons from early
warnings: The precautionary principle 1896–2000, The precautionary principle
and early warnings of chemical contaminationof the Great Lakes, Michael
Gilbertson ,p. 126 – 132, Copenhagen: European Environment Agency
http://www.eea.europa.eu/publications/environmental_issue_
report_2001_22/Issue_Report_No_22.pdf
3 This principle can now be found in numerous regional treaties and
global conventions. One well-known example is the Rio Declaration (UN
Conference on Environment and Development (1992) Rio Declaration on
Environment and Development.
http://www.un.org/documents/ga/conf151/aconf15126-1annex1.htm).
Principle 15 of the Rio Declaration states: “Where there are threats of
serious or irreversible damage, lack of full scientific certainty shall not
be used as a reason for postponing cost-effective measures to prevent
environmental degradation.”

78 Astrup Jensen A, Brunn Poulsen P & Bossi R (2008). Survey
and environmental/health assessment of fluorinated substances in
impregnated consumer products and impregnating agents, Survey of
Chemical Substances in Consumer Products No 99, Copenhagen: Danish
Environmental Protection Agency.
http://www2.mst.dk/common/Udgivramme/Frame.asp?http://www2.mst.
dk/udgiv/publications/2008/978-87-7052-845-0/html/default_eng.htm

4 Nakachi S (2010). The Pollutant Release and Transfer Register (PRTR)
in Japan and Korean Toxic Releases Inventory (TRI)– an evaluation of their
operation, Tokyo: Toxic Watch Network, p13.
http://www.toxwatch.net/en/pdf/PRTR_JAPAN_1206.pdf

79 Walters A & Santillo D (2006). Uses of Perfluorinated Substances, Technical
Note 06/2006, Exeter: Greenpeace Research Laboratories.
http://www.greenpeace.to/publications/uses-of-perfluorinated-chemicals.pdf

6 European Commission (2009), Commission Regulation (EC) No 552/2009
of 22 June 2009 amending Regulation (EC) No 1907/2006 of the European
Parliament and of the Council on the Registration, Evaluation, Authorisation
and Restriction of Chemicals (REACH) as regards Annex XVII, Official
Journal L 164. 26.6.2009.

80 Walters A & Santillo D (2006) op cit.

5 Greenpeace (2011). Hidden consequences, op. cit. Section 2.4 by Aldert
van der Kooij

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109

References (continued)
7 “Discharge” refers to all discharges, emissions and losses, ie all pathways
of release.
8 Typically, one generation is understood as equivalent to 20 to 25 years.
9 For example,“no data, no market” provisions in EU REACH Regulation
(see European Commission 2009).
10 Meaning regularly revised based on latest evidence
11 Classification of hazardousness to be based on intrinsic properties
such as whether it is persistent; bioaccumulative; toxic; carcinogenic,
mutagenic and reprotoxic; hormone disruptive or of equivalent concern.
See Greenpeace Policy Q and A - Q5 Which hazardous chemicals should
we tackle first?
http://www.greenpeace.org/international/Global/international/publications/
toxics/Water%202011/HCPolicy.pdf
12 OSPAR (2004). Nonylphenol/nonylphenolethoxylates, OSPAR Priority
Substances Series, updated edition, London: OSPAR Commission
13 Jobling S, Reynolds T, White R et al (1995) op cit.
14 Jobling S, Sheahan D, Osborne JA et al (1996) op cit.
15 Commission Regulation (EC) No 552/2009 of 22 June 2009 amending
Regulation (EC) No 1907/2006 of the European Parliament and of the
Council on the Registration, Evaluation, Authorisation and Restriction
of Chemicals (REACH) as regards Annex XVII, Official Journal L 164.
26.6.2009, pp7-31.
http://eur-lex.europa.eu/LexUriServ/LexUriServ.do?uri=OJ:L:2009:164:00
07:0031:EN:PDF
Prior to REACH, nonylphenols were restricted from 2005 under Directive
2003/53/EC of The European Parliament and of the Council of 18 June
2003 amending for the 26th time Council Directive 76/769/EEC relating to
restrictions on the marketing and use of certain dangerous substances and
preparations (nonylphenol, nonylphenol ethoxylate and cement), which was
repealed on 1 June 2009 by Commission Regulation 552/2009 (above).
16 Howdeshell KL, Wilson VS, Furr J, Lambright CR, Rider CV, Blystone
CR, Hotchkiss AK & Gray LE Jr (2008). “A mixture of five phthalate esters
inhibits fetal testicular testosterone production in the Sprague Dawley rat
in a cumulative dose additive manner”, Toxicological Sciences, vol 105,
pp153–165
17 European Chemicals Agency (2010). Evaluation of new scientific
evidence concerning the restrictions contained in Annex XVII to regulation
(EC) No 1907/2006 (REACH): Review of new available information for bis
(2-ethylhexyl) phthalate (DEHP), European Chemicals Agency
http://echa.europa.eu/doc/reach/restrictions/dehp_echa_review_
report_2010_6.pdf
18 Commission Regulation (EU) No 143/2011 of 17 February 2011
amending Annex XIV to Regulation (EC) No 1907/2006 of the European
Parliament and of the Council on the Registration, Evaluation, Authorisation
and Restriction of Chemicals (‘REACH’), Official Journal L44 18.2.2011,
pp.2-6. While the date of the definitive ban is set as February 2015 there are
some exemptions (such as use in medical packaging), and companies can
still apply for further exemptions until August 2013.
19 Talsness CE (2008). “Overview of toxicological aspects of
polybrominated diphenyl ethers: A flame-retardant additive in several
consumer products”, Environmental Research, vol 108, pp158–167.
20 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit.
(REACH). Existing restrictions set out in the Marketing and Use Directive
(76/769/EEC) on the marketing and use of certain dangerous substances
and preparations (pentabromodiphenyl ether, octabromodiphenyl ether)
were carried over to REACH. Directive 76/769/EEC was repealed on 1 June
2009.

110

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

21 EU (2000). Directive 2000/60/EC establishing a framework for
Community action in the field of water policy, Official Journal L327
22.12.2000, pp1-72
22 EU (2000). Directive 2008/105/EC of the European Parliament and of
the Council of 16 December 2008 on environmental quality standards in the
field of water policy, Official Journal L348 24.12.2008 pp84-97
23 Gregory P (2007). “Toxicology of textile dyes”, Chapter 3 in Christie, R.
(ed.) Environmental aspects of textile dyeing, Woodhead Publishing.
24 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit.
(REACH). Azo colourants were first restricted by the EU (2002) Directive
2002/61/EC of the European Parliament and of the Council of 19 July 2002
amending for the nineteenth time Council Directive 76/769/EEC (relating to
restrictions on the marketing and use of certain dangerous substances and
preparations (azocolourants), Official Journal L 243, 11.09.2002, pp.15-18).
The restrictions set out in the Marketing and Use Directive (76/769/EEC)
were carried over to REACH. Directive 76/769/EEC was repealed on 1 June
2009.
25 OSPAR (2004). OSPAR background document on organic tin
compounds, updated edition, London: OSPAR Commission.
26 EU (2000). Directive 2000/60/EC, op cit.
27 Commission Regulation (EU) No 276/2010 of 31 March 2010 amending
Regulation (EC) No 1907/2006 of the European Parliament and of the
Council on the Registration, Evaluation, Authorisation and Restriction of
Chemicals (REACH) as regards Annex XVII (dichloromethane, lamp oils
and grill lighter fluids and organostannic compounds), Official Journal L86
1.4.2010, pp7-12
28 Giesy JP & Kannan K (2001) op cit..
29 Kannan K, Corsolini S, Falandysz J et al (2002) op cit.
30 Lau C, Anitole K, Hodes C et al (2007) op cit.
31 Jensen A & Leffers H (2008) op cit.
32 Kannan K, Corsolini S, Falandysz J et al (2002) op cit.
33 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit.
(REACH)
34 Government of Canada (2007). “Chemicals Management Plan –
Implementation timetable”.
http://www.chemicalsubstanceschimiques.gc.ca/plan/table-tableau_e.
html
35 Agency for Toxic Substances and Disease Registry (2002) Toxicological
profile for hexachlorobenzene, United States Public Health Service, Agency
for Toxic Substances and Disease Registry
36 EU (2000) Directive 2000/60/EC op cit.
37 Commission Regulation (EU) No 757/2010 of 24 August 2010 amending
Regulation (EC) No 850/2004 of the European Parliament and of the
Council on persistent organic pollutants as regards Annexes I and III, Official
Journal L223 25.8.2010, pp.29-36
38 Agency for Toxic Substances and Disease Registry (2006, 1989)
Toxicological profiles for 1,1,1-trichloroethane & 1,1,2-trichloroethane,
United States Public Health Service, Agency for Toxic Substances and
Disease Registry
39 The use of TCE is regulated via Entry 34 of Annex 17 of the EU chemical
law (Regulation (EC) No 1907/2006 concerning the Registration, Evaluation,
Authorisation and Restriction of Chemicals (REACH)) and is not to be
placed on the market or used in concentrations equal to or greater than 0.1
per cent by weight of product for sale to the general public and in diffusive
applications such as surface cleaning and cleaning of fabrics. Commission
Regulation (EC) No 552/2009 of 22 June 2009 (REACH) op cit.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

40 OSPAR (2004). Pentachlorophenol, OSPAR Priority Substances Series
2001, updated 2004, OSPAR Convention for the Protection of the Marine
Environment of the North-East Atlantic, OSPAR Commission, London,
ISBN 0-946956-74: 31 pp.
http://www.ospar.org/documents/dbase/publications/p00138_BD%20
on%20pentachlorophenol.pdf
41 Since 1991, all PCP-containing products sold and used in the EU have
been imported (EU production was banned under Directive 76/769/EEC).
Now entry number 22 of Annex 17 of the EU chemical law prohibits the
marketing and use in the EU of PCP and its salts and esters in products in a
concentration equal to or greater than 0.1 per cent (Commission Regulation
(EC) No 552/2009 of 22 June 2009, op cit. (REACH)).
42 OSPAR (2001). Short chain chlorinated paraffins, OSPAR Hazardous
Substances Series, London: OSPAR Commission, London, ISBN 0 946956
77: 18 pp.
43 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit.
(REACH)

References

10 Grupo Cortefiel, “Cortefiel press dossier,” n.d., 9, (accessed June 20,
2011).
http://www.grupocortefiel.com/files/assets/0000/6404/Press_dossier_
GrCortefiel_28.01.11_2.pdf
11 Grupo Cortefiel, “About us » history
http://www.grupocortefiel.com/en/about-us/history
12 Grupo Cortefiel, “About us » Grupo Cortefiel,” n.d.
http://www.grupocortefiel.com/en/about-us ().
13 Grupo Cortefiel, “Corporate Responsibility » Grupo Cortefiel,” n.d.
http://www.grupocortefiel.com/en/corporate-responsibility
14 Grupo Cortefiel, “Grupo Cortefiel Sustainability Report 2009,” n.d.
http://www.grupocortefiel.com/en/corporate-responsibility
15 http://about.hm.com/gb/abouthm/factsabouthm/
ourbusinessconcept__ourphilo.nhtml
16 http://about.hm.com/gb/abouthm/factsabouthm__facts.nhtml

44 Agency for Toxic Substances and Disease Registry (2007, 2008).
Toxicological profiles for lead and cadmium, United States Public Health
Service, Agency for Toxic Substances and Disease Registry

17 Fast Retailing Co Ltc. “Industry Ranking | FAST RETAILING CO., LTD.,”
2011 04 27.
http://www.fastretailing.com/eng/ir/direction/position.html

45 United Nations Environment Programme (2002). Global mercury
assessment, Geneva: UNEP.
http://www.chem.unep.ch/mercury/Report/GMA-report-TOC.htm

18 http://www.hm.com/filearea/corporate/fileobjects/pdf/en/CSR_
REPORT2010_PDF_1302846254219.pdf

46 National Institute of Environmental Health Sciences (2009). Report on
carcinogens, eleventh edition; substance profiles, chromium hexavalent
compounds, US National Institute of Environmental Health Sciences
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47 Baral A, Engelken R, Stephens W, Farris J & Hannigan R (2006).
“Evaluation of aquatic toxicities of chromium and chromium-containing
effluents in reference to chromium electroplating industries”, Archives of
Environmental Contamination and Toxicology, vol. 50, no. 4, 496-502

19 Lacoste press kit”, n.d., 7, http://www.lacoste.com/library/download/
pdf/LACOSTE_presskit_en.pdf.
20 Ibid 1.
21 Ibid 9.
22 http://www.pvh.com/news_release.aspx?reqid=1548045
23 http://en.wikipedia.org/wiki/Van_Heusen

48 EU (2000) Directive 2000/60/EC op cit.

24 http://www.reuters.com/finance/stocks/companyProfile?rpc=66&sym
bol=PVH

49 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit.
(REACH)

25 http://www.fashion-incubator.com/archive/apparel-price-pointcategories/
26 http://www.pvh.com/news_release.aspx?reqid=1548045

Appendix 1

27 http://www.pvh.com/brands.html
28 http://www.pvh.com/brands.html

1 Adidas website, accessed February 2011 |http://www.Adidas-group.
com/en/sustainability/suppliers_and_workers/code_of_conduct/default.
aspx

29 http://www.pvh.com/responsibility.html

2 Adidas Group, 2010, Annual Report 2009, p. 227, accessed December
2010.
http://www.Adidas-group.com/en/investorrelations/assets/pdf/annual_
reports/2009/GB_2009_En.pdf

31 Nike CRR 2007-9, accessed April 2011
http://www.nikebiz.com/crreport/content/environment/4-1-0-overview.
php?cat=overview

3 Adidas Group, Sustainability, accessed December 2010
http://www.adidasgroup.com/en/sustainability/welcome.aspx
4 http://www.bauer.com/career
5 http://www.bauerir.com/site/company/growth.php
6 http://invest.nike.com/phoenix.zhtml?c=100529&p=irol-newsArticle_
print&ID=1110938&highlight= (visit 26 April 2011)
7 http://phx.corporate-ir.net/phoenix.zhtml?c=242945&p=irolnewsArticle&ID=1538093&highlight=
8 http://www.bauerir.com/site/company/brands.php(visit 26 April 2011)

30 http://www.pvh.com/pdf/environmental_policy.pdf

32 Nike CRR 2007-9, accessed April 2011.
http://www.nikebiz.com/crreport/content/workers-and-factories/3-11-0interactive-map.php?cat=map
33 Puma.com website, April 2011
http://vision.puma.com/us/en/
34 Puma AG. 2010. Annual report 2009.
35 Youngor website, April 2011
http://en.youngor.com/responsibility.do?cid=200811190221102735
36 China National Garment Association, 2010, “Winners of China Winner
List of China Garment Industry Prize,”
http://www.cnga.org.cn/engl/powerful/top100.asp

9 http://phx.corporate-ir.net/phoenix.zhtml?c=242945&p=irolgovHighlights
Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

111

References (continued)
37 Leaders magazine, 2010, “Stringing the Pearls Together – Interview with
Li Rucheng,” in Leaders magazine January February March 2010.
http://www.leadersmag.com/issues/2010.1_Jan/PDFs/BRIC/Li%20
Rucheng.pdf

60 Investor Relations Asia Pacific, “irasia.com,” Li Ning Company Limited
Annual Reports 2009, n.d. 131-136.
http://www.irasia.com/listco/hk/lining/annual/index.htm

38 Dun & Bradstreet, Inc (2010), Business Information Report : Youngor
Group Co. Ltd.
http://www.dnb.com/

61 Li Ning Company Limited, “Li Ning Company Limited,” 79. Prospectus
2004 Placing & Public Offer, 2004, 66.
http://www.lining.com/EN/investors/inside-4_5.html (accessed January
27, 2011).

39 Youngor Group Ltd (2008). “Youngor - Knitting,”
http://en.youngor.com/business.do?action=classinfo&pid=20081119095
0271540&cid=200907081032387512

62 China Sporting Goods Federation, “China Sporting Goods Federation,”
Li Ning Published First CSRReport on Sporting Goods, July 28, 2009.
http://en.csgf.org.cn/Sportnews_show.aspx?ArticleID=184

40 Ningbo Youngor Fashion Co Ltd (2008). “Brand Cooperation”.
http://www.youngor.com/youngor_sub/index.do?action=info&sid=20090
3130340424300&pid=e2009031303404243003&cid=20090408033942
1575&lan=EN

63 Hoover’s Inc (2010), Hoover’s Inc (2010) Industry profile: Apparel
manufacture.
http://www.hoovers.com/industry/apparel/1161-1.html Registration
required.

41 Youngor Group Ltd (2008). “Youngor - Branded Garments business
Review”.
http://en.youngor.com/business.do?action=info&pid=200811190950271
540&cid=200811211010001550

64 Euromonitor (2010), Euromonitor (2010) Market Share Apparel 2003
– 2008
http://www.imis.euromonitor.com

42 Youngor website, May 2011
http://en.youngor.com/about.do?cid=200811070246144574
43 Youngor Group Ltd., 2008, “Youngor - Branded Garments business
Review,” op cit.
44 Youngor website, May 2011
http://en.youngor.com/business.do?action=classinfo&pid=20081119095
0271540&cid=200811211046396449
45 Youngor website, April 2011
http://en.youngor.com/responsibility.do?action=display&
cid=200811190221474000
46 http://en.wikipedia.org/wiki/Abercrombie_%26_Fitch
47 http://library.corporate-ir.net/library/61/617/61701/items/249197/
Piper_June_2007.pdf
48 http://www.icsc.org/srch/sct/sct0308/retailing_gilly.php
49 http://www.focus.de/finanzen/news/unternehmen/tid-20921/
abercrombie-und-fitch-teuer-dunkel-hip_aid_587281.html

65 Puma AG Rudolf Dassler Sport (PUM-FF), graph from: Christoph
Dolleschal, “Adidas,” Equity Research, Commerzbank, 28 February 2008
http://www.wikinvest.com/stock/Puma_AG_Rudolf_Dassler_Sport_
(PUM-FF),
66 Casseres, B G, Petkova P, Pattabiraman S, Nike Inc. and the Athletic
Footwear Industry Strategy and Competition Analysis, 19 May 2010, p.15
http://www.scribd.com/doc/38643840/Nike-Strategy-Analysis-FinalJun-2010

Appendix 2
1 http://www.blazek.eu/cs/o-spolecnosti.html
2 Inter Ikea Centre Group, “Blažek”, 2011.
http://www.ostrava.avionshoppingpark.cz/en-gb/store-locator/blazek
3 http://www.blazek.eu/cs/o-spolecnosti.html
4 Ibid.
5 http://www.macysinc.com/AboutUs/

50 http://www.wikinvest.com/wiki/Abercrombie

6 http://www.macysinc.com/AboutUs/Default.aspx

51 http://www.wikinvest.com/wiki/Abercrombie

7 http://www.macysinc.com/Macys/privateexclusive.aspx

52 http://www.abercrombieoutlet.us/First-Abercrombie-&-Fitch-to-openAsian-restaurant!-Day-sales-record!-n-29.html

8 http://www.macysinc.com/aboutus/sustainability/five-point-action-plan.
aspx

53 http://jasonfight.crearblog.com/?p=175

9 Nautica, “Nautica: Customer Service,” About Nautica, n.d
http://www.nautica.com/home/index.jsp

54 Meters/bonwe. 2011. Brief introduction.
http://corp.metersbonwe.com/english_intro.html (accessed June 20 2011)
55 Meters/bonwe. 2011. Brief introduction.
http://corp.metersbonwe.com/english_intro.html (accessed June 20 2011)
56 Meters/bonwe (2008). Meters/bonwe 2008 CSR report, p8.
http://corp.metersbonwe.com/investor/investor_index.php
57 http://www.lining.com/EN/company/inside-1_3.html
58 Li Ning Company Limited, “Welcome to Li Ning Company Limited.” Li
Ning Company Limited, 2010.
http://www.lining.com/EN/home/index.html (accessed January 27, 2011).
59 Investor Relations Asia Pacific, “irasia.com,” 24. Li Ning Company
Limited Interim Reports, 2010.
http://www.irasia.com/listco/hk/lining/interim/index.htm

112

Dirty Laundry: Unravelling the corporate connections to toxic water pollution in China

10 Advameg, Inc., “Nautica Enterprises, Inc. - Company Profile,
Information, Business Description, History, Background Information on
Nautica Enterprises, Inc..”
11 http://www.textilwirtschaft.de
12 VF Corporation. “VF Corporation - Our Brands,” Our brands, n.d.
http://www.vfc.com/brands
13 VF Corporation. “VF Corporation 10k”, n.d., 7.
http://phx.corporate-ir.net/External.File?item=UGFyZW50SUQ9NDE5NjU
yfENoaWxkSUQ9NDMyOTU4fFR5cGU9MQ==&t=1.
14 VF Corporation “VF Corporation- Global Compliance Principles”, n.d., 3.
http://www.vfc.com/VF/corporation/resources/images/Content-Pages/
Corporate-Responsibility/VFC-Global-Compliance-Principles.pdf.

Greenpeace
International

Dirty Laundry
Unravelling the corporate
connections to toxic water
pollution in China

15 Oxford Industries Inc., “Oxford Industries - apparel company,” n.d.,
http://www.apparelsearch.com/financial/stocks/wholesale/Oxford_
Industries.htm
16 Oxford Industries,.“Oxford Apparel 10-k 2009,” n.d., 7.
http://www.sec.gov/Archives/edgar/data/75288/000104746910002998/
a2197649z10-k.htm
17 Li & Fung Limited, “lifunggroup.com - Li & Fung Group - Sustainability >
Environment,” n.d..
http://www.lifunggroup.com/eng/sustainability/environment.php
18 Peerless Clothing Inc. “Peerless Clothing - Home,” n.d.
http://www.peerless-clothing.com/home.htm
19 Peerless Clothing Inc.,“Peerless Clothing - Home,” n.d.
http://www.peerless-clothing.com/home.htm
20 VM ware Inc. “Customer Case Study Peerless Clothing,” n.d. 1
http://www.vmware.com/files/pdf/customers/09Q1_cs_vmw_Peerless_
english_R2.pdf (accessed June 20, 2011).

References

44 http://www.kohlscorporation.com/PressRoom/PDFs/2009/2009Report
ShareholdersSocialResponsibility.pdf
45 Zhejiang Semir Garment Co., Ltd. 2011. Responsibility. http://www.
semirbiz.com/en/corporate-profile/responsibility.aspx
46 China Value. 2007. Semir, please pay attention to your
responsibilities. September 2007. http://www.chinavalue.net/Article/
Archive/2007/9/18/81271.html (in Chinese).
47 Fast Retailing Co Ltd. “Industry Ranking | FAST RETAILING CO., LTD.,”
December 20, 2010
http://www.fastretailing.com/eng/ir/direction/position.html.
48 “Performance by Group Operation | FAST RETAILING CO., LTD.,” n.d.,
http://www.fastretailing.com/eng/ir/financial/group.html
49 “CSR Report 2011 | FAST RETAILING CO., LTD.,”, http://www.
fastretailing.com/eng/csr/report/
50 Ibid.

21 Ibid.

51 Yishion. 2011. About us. http://www.yishion.com.cn/#aboutus

22 Polo Ralph Lauren Corp, “10-k report 2009-2010 polo ralph lauren,”
n.d., 34
http://www.sec.gov/Archives/edgar/
data/1037038/000095012310055188/y81773e10vk.htm

Appendix 3

23 Ibid., 34.
24 Polo Ralph Lauren Corp, “10-k report 2009-2010 polo ralph lauren,” 16.
25 Ibid., 26.
26 http://www.wikinvest.com/wiki/American_Eagle_Outfitters_(AEO)
27 http://www.wikinvest.com/wiki/American_Eagle_
Outfitters_%28AEO%29
28 http://www.just-style.com/news/american-eagle-to-open-stores-inchina-hong-kong_id107951.aspx
29 http://news.alibaba.com/article/detail/business-in-china/100329531-1american-eagle-open-stores-hk%252C.html
30 http://www.ae.com/web/corp/responsibility.jsp?topic=environment
31 http://www.carters.com/Corporate-Site-Our-Brands-Landing-Page/
corporateOurBrands,default,pg.html
32 http://phx.corporate-ir.net/External.File?item=UGFyZW50SUQ9NDIwO
DM5fENoaWxkSUQ9NDM0NDAzfFR5cGU9MQ==&t=1
33 http://www.wikinvest.com/stock/Gap_(GPS)
34 http://www.wikinvest.com/stock/Gap_(GPS)
35 http://www.rttnews.com/content/topstories.aspx?Id=1445260)
36 http://www2.gapinc.com/GapIncSubSites/csr/Utility/resources.shtml
37 http://www2.gapinc.com/GapIncSubSites/csr/Utility/resources.shtml
38 http://www2.gapinc.com/GapIncSubSites/csr/Utility/resources.shtml
39 http://www.jcpenneybrands.com/ )
40 http://www.jcpenney.net/JCPenney/media/SiteImages/PDF%20doc/
JCPenneyMattersPrinciple.pdf
41 http://www.wikinvest.com/wiki/Kohl%27s_(KSS)
42 http://www.wikinvest.com/wiki/Kohl%27s_(KSS)
43 http://www.kohlsgreenscene.com/

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on chemicals, pesticides and biotechnology ENV/JM/RD(2002)17/
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3 Hekster FM, Laane RWPM & De Voogt P (2003). “Environmental and
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26 Use of TCE is restricted via Entry 34 of Annex 17 of the EU chemical law
(Regulation (EC) No 1907/2006 concerning the Registration, Evaluation,
Authorisation and Restriction of Chemicals (REACH)) to concentrations
equal to or greater than 0.1 per cent by weight of product for sale to the
general public and in diffusive applications such as surface cleaning and
cleaning of fabrics. Commission Regulation (EC) No 552/2009 of 22 June
2009 (REACH) op.cit.
27 Agency for Toxic Substances and Disease Registry (1989) Toxicological
profiles for 1,1,2-trichloroethane, United States Public Health Service,
Agency for Toxic Substances and Disease Registry, December 1989.
28 Agency for Toxic Substances and Disease Registry (2006) Toxicological
profiles for 1,1,1-trichloroethane, United States Public Health Service,
Agency for Toxic Substances and Disease Registry, July 2006

15 Novotný et al (2006) op cit.

29 ATSDR (2004) Toxicological profile for copper, United States Public
Health Service, Agency for Toxic Substances and Disease Registry,
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16 Sendelbach LE (1989). A review of the toxicity and carcinogenicity of
anthraquinone derivatives. Toxicology 57: 227-240

30 ATSDR (2005) Toxicological profile for nickel. Agency for Toxic
Substances and Disease Registry, US Public Health Service, August 2005

17 Wei Y, Han I-K, Hu M, Shao M, Zhang J & Tang X (2010). Personal
exposure to particulate PAHs and anthraquinone and oxidative DNA
damages in humans. Chemosphere 81: 1280-1285

31 ATSDR (2008b) Toxicological profile for chromium, United States
Public Health Service, Agency for Toxic Substances and Disease Registry,
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18 Brigden K et al (2011) op cit.

32 Comber SDW, Merrington G, Sturdy L, Delbeke K, van Assche F (2008).
Copper and zinc water quality standards under the EU Water Framework
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19 Gregory P (2007). “Toxicology of textile dyes”, Chapter 3 in Christie, R.
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20 Commission Regulation (EC) No 552/2009 of 22 June 2009, op cit
(REACH). Existing restrictions set out in the Marketing and Use Directive
(76/769/EEC) were carried over to REACH. Directive 76/769/EEC was
repealed on 1 June 2009. Azocolourants were previously restricted under
the EU (2002) Directive 2002/61/EC of the European Parliament and of the
Council of 19 July 2002 amending for the nineteenth time Council Directive
76/769/EEC relating to restrictions on the marketing and use of certain
dangerous substances and preparations (azocolourants), Official Journal L
243, 11.09.2002, pp15-18
21 Pinheiro HM, Touraud E & Thomas O (2004). Aromatic amines
from azo dye reduction: status review with emphasis on direct UV
spectrophotometric detection in textile industry wastewaters. Dyes and
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33 Guangdong Province (2001). Guangdong Provincial Water Pollutant
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34 MEP (1992). GB 4287-92, the Discharge Standard of Water Pollutants
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Protection (MEP), The People’s Republic of China.
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35 ATSDR (2008b). Toxicological profile for chromium, United States
Public Health Service, Agency for Toxic Substances and Disease Registry,
September 2008

22 Carvalho G, Marques R, Lopes AR, Faria C, Noronha JP, Oehmen
A, Nunes OC & Reis MAM (2010). Biological treatment of propanil and
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36 IPPC (2003). Reference document on best available techniques for
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23 Dom N, Knapen D, Benoot D, Nobels I & Blust R (2010). Aquatic
multi-species acute toxicity of (chlorinated) anilines: Experimental versus
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38 IPPC (2003) op cit.

24 Since 1991, all PCP-containing products sold and used in the EU have
been imported (EU production was banned under Directive 76/769/EEC).
Now entry number 22 of Annex 17 of the EU chemical law REACH prohibits
the marketing and use in the EU of PCP and its salts and esters in products
in a concentration equal to or greater than 0.1 per cent. Commission
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Dirty Laundry
Unravelling the corporate
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